+++ DISCLAIMER +++

Nothing you see here is real, even though the conversion or the presented background story might be based historical facts. BEWARE!

  

Some background:

The Wasp was a transonic British jet-powered fighter aircraft that was developed by Folland for the Royal Air Force (RAF) during the late 1940s and early 1950s. The Wasp’s origins could be traced back to a privately funded 1952 concept for a bigger and more capable day fighter aircraft than Folland’s very light Midget/Gnat. The Wasp’s development had been continued until the Gnat’s service introduction, and by then it had evolved under the handle “Fo-145” into a supersonic aircraft that took advantage of the new Armstrong Siddeley Sapphire turbojet engine, swept wings and area rule. The aircraft was built with the minimum airframe size to take the reheated Saphire and a radar system that would allow it to deploy the new de Havilland Blue Jay (later Firestreak) guided air-to-air missile. In this form the aircraft was expected to surpass the Royal Air Force’s contemporary day fighter, the only gun-armed Hawker Hunter, which had been in service since 1954, while using basically the same engine as its F.2 variant, in both performance and armament aspects. The missile-armed Wasp was also expected to replace the disappointing Supermarine Swift and the Fairey Fireflash AAMs that had been developed for it.

The Wasp strongly resembled the smaller Gnat, with a similar but much thinner shoulder mounted wing, with a sweep of 35° at quarter chord, but the new aircraft featured some innovations. Beyond the area-ruled fuselage, the aircraft had full-span leading edge slats and trailing edge flaps with roll control achieved using spoilers rather than traditional ailerons. Anticipating supersonic performance, the tailplane was all-moving. The cockpit had been raised and offered the pilot a much better all-round field of view.

 

The Wasp was armed with four 30 mm (1.18 in) ADEN cannon, located under the air intakes. Each gun had a provision of 125 rounds, from form a mutual ventral ammunition bay that could be quickly replaced. Four underwing hardpoints could carry an ordnance load of up to 4.000 lb, and the Wasp’s main armament consisted of up to four IR-guided “Firestreak” AAMs. To effectively deploy them, however, a radar system was necessary. For launch, the missile seeker was slaved to the Wasp’s AI.Mk.20 X-band radar until lock was achieved and the weapon was launched, leaving the interceptor free to acquire another target. The AI.Mk.20 had been developed by EKCO since 1953 under the development label “Green Willow” for the upcoming EE Lightning interceptor, should the latter’s more complex and powerful Ferranti AIRPASS system fail. A major advantage of the AI.Mk.20 was that it had been designed as a single unit so it could be fit into the nose of smaller single-seat fighters, despite its total weight of roughly 400 lb (200 kg). For the Firestreak AAM, EKCO had developed a spiral-scan radar with a compact 18 in (460 mm) antenna that offered an effective range of about 10 miles (16 km), although only against targets very close to the centerline of the radar. The radar’s maximum detection range was 25 mi (40 km) and the system also acted as a ranging radar, providing range input to the gyro gunsight for air-to-air gunnery.

Beyond Firestreaks, the Wasp could also carry drop tanks (which were area-ruled and coulc only be carried on the inner pair of pylons), SNEB Pods with eighteen 68 mm (2.68 in) unguided rocket projectiles against air and ground targets, or iron bombs of up to 1.000 lb caliber. Other equipment included a nose-mounted, and a forward-facing gun camera.

 

The Royal Air Force was sufficiently impressed to order two prototypes. Since the afterburning version of the Sapphire was not ready yet, the first prototype flew on 30 July 1954 with a non-afterburning engine, an Armstrong Siddeley Sapphire Sa.6 with 8,000 lbf (35.59 kN). In spite of this lack of power the aircraft nevertheless nearly reached Mach 1 in its maiden flight. The second prototype, equipped with the intended Sapphire Sa.7 afterburning engine with 11,000 lbf (48.9 kN) thrust engine, showed the aircraft’s full potential. The Wasp turned out to have very good handling, and the RAF officially ordered sixty Folland Fo-145 day-fighters under the designation “Wasp F.Mk.1”. The only changes from the prototypes were small leading-edge extensions at the wing roots, improving low speed handling, esp. during landings and at high angles of incidence in flight.

 

Most Wasps were delivered to RAF Germany frontline units, including No. 20 and 92 Squadrons based in Northern Germany. However, the Wasp’s active service did not last long, because technological advancements quickly rendered the aircraft obsolete in its original interceptor role. The Wasp’s performance had not turned out as significantly superior to the Hunter as expected. Range was rather limited, and the aircraft turned out to be underpowered, since the reheated Sapphire Sa6 did not develop as much power as expected. The AI.Mk.20 radar was rather weak and capricious, too, and the Firestreak was an operational nightmare. The missile was, due to its solid Magpie rocket motor and the ammonia coolant for the IR seeker head, highly toxic and RAF armorers had to wear some form of CRBN protection to safely mount the missile onto an aircraft. Furthermore, unlike modern missiles, Firestreak’s effectiveness was very limited since it could only be fired outside cloud - and over Europe or in winter, skies were rarely clear.

 

Plans for a second production run of the Folland Wasp with a more powerful Sapphire Sa7R engine with a raised thrust of 12,300 lbf (54.7 kN) and updated avionics were not carried out. During the 1960s, following the successful introduction of the supersonic English Electric Lightning in the interceptor role, the Wasp, as well as the older but more prosperous and versatile Hunter, transitioned to being operated as a fighter-bomber, advanced trainer and for tactical photo reconnaissance missions.

This led to a limited MLU program for the F.Mk.1s and conversions of the remaining airframes into two new variants: the new main version was the GR.Mk.2, a dedicated CAS/ground attack variant, which had its radar removed and replaced with ballast, outwardly recognizable through a solid metal nose which replaced the original fiberglass radome. Many of these machines also had two of the 30mm guns removed to save weight. Furthermore, a handful Wasps were converted into PR.Mk.3s. These had as set of five cameras in a new nose section with various windows, and all the guns and the ammunition bay were replaced with an additional fuel tank, operating as pure, unarmed reconnaissance aircraft. When Folland was integrated into the Hawker Siddeley Group in 1963 the aircraft’s official name was changed accordingly, even though the Folland name heritage persisted.

 

Most of these aircraft remained allocated to RAF Germany units and retired towards the late Sixties, but four GR.Mk.2s were operated by RAF No. 57 (Reserve) Squadron and based at No. 3 Flying Training School at Cranwell, where they were flown as adversaries in dissimilar aerial combat training. The last of the type was withdrawn from service in 1969, but one aircraft remained flying with the Aeroplane and Armament Experimental Establishment at Boscombe Down until 24 January 1975.

  

General characteristics:

Crew: 1

Length: 45 ft 10.5 in (13.983 m)

Wingspan: 31 ft 7.5 in (9.639 m)

Height: 13 ft 2.75 in (4.0323 m)

Wing area: 250 sq ft (23 m2)

Empty weight: 13,810 lb (6,264 kg)

Gross weight: 21,035 lb (9,541 kg)

Max takeoff weight: 23,459 lb (10,641 kg)

 

Powerplant:

1× Armstrong Siddeley Sapphire Sa.6, producing 7,450 lbf (33.1 kN) thrust at 8,300 rpm,

military power dry, and 11,000 lbf (48.9 kN) with afterburner

 

Performance:

Maximum speed: 631 kn (726 mph, 1,169 km/h) / M1.1 at 35,000 ft (10,668 m)

654 kn (753 mph; 1,211 km/h) at sea level

Cruise speed: 501 kn (577 mph, 928 km/h)

Range: 1,110 nmi (1,280 mi, 2,060 km)

Service ceiling: 49,000 ft (15,000 m)

Rate of climb: 16,300 ft/min (83 m/s)

Wing loading: 84 lb/sq ft (410 kg/m2)

Thrust/weight: 0.5

 

Armament:

4× 30 mm (1.18 in) ADEN cannon, 125 rounds per gun

4× underwing hardpoints for a total external ordnance of 4.000 lb, including Firestreak AAMs,

SNEB pods, bombs of up to 1.000 lb caliber or two 125 imp gal (570 l) drop tanks

  

The kit and its assembly

This kit travesty is a remake of a simple but brilliant idea of fellow modeler chrisonord at whatifmodellers’com (www.whatifmodellers.com/index.php?topic=48434.msg899420#m...), who posted his own build in late 2020: a Grumman Tiger in standard contemporary RAF colors as Folland Wasp GR.Mk.2. The result looked like a highly credible “big brother” or maybe successor of Folland’s diminutive Midge/Gnat fighter, something in the Hawker Hunter’s class. I really like the idea a lot and decided that it was, one and a half years later, to build my personal interpretation of the subject – also because I had a Hasegawa F11F kit in The Stash™ without a proper plan.

 

The Tiger was built basically OOB – a simple and straightforward affair that goes together well, just the fine, raised panel lines show the mould’s age. The only changes I made: the arrester hook disappeared under PSR, small stabilizer fins (from an Italeri BAe Hawk) were added under the tail section, and I replaced the Tiger’s rugged twin wheel front landing gear with a single wheel alternative, left over from a Matchbox T-2 Buckeye. On the main landing gear, the rearward-facing stabilizing struts were deleted (for a lighter look of a land-based aircraft) and their wells filled with putty. A late modification were additional swing arms for the main landing gear, though: once the kit could sit on its own three feet, the stance was odd and low, esp. under the tail – probably due to the new front wheel. As a remedy I glued additional swing arm elements, made from 1mm steel wire, under the original struts, what moved the main wheel a little backwards and raised the main landing gear my 1mm. Does not sound like much, but it was enough to lift the tail and give the aircraft a more convincing stance and ground clearance.

 

The area-ruled drop tanks and their respective pylons were taken from the Hasegawa kit. For a special “British” touch – because the Tiger had a radome (into which no radar was ever fitted, though) – I added a pair of Firestreak AAMs on the outer underwing stations, procured from a Gomix Gloster Javelin (which comes with four of these, plus pylons).

  

Painting and markings:

Since the RAF theme was more or less settled, paintwork revolved around more or less authentical colors and markings. The Wasp received a standard RAF day fighter scheme from the late Fifties, with upper camouflage in RAF Dark Green/Dark Sea Grey and Light Aircraft Grey undersides with a low waterline. I used Humbrol 163, 106 and 166, respectively – Ocean Grey was used because I did not have the proper 164 at hand, but 106 also offered the benefit of a slightly better contrast to the murky Dark Green. A black ink washing was applied plus some panel post-shading. The silver leading edges on wings, stabilizers and fin were created with decal sheet material, avoiding the inconvenience of masking.

 

The cockpit interior was painted in a very dark grey (Revell 09, Anthracite) while the landing gear, wheels and wells received a greyish-metallic finish (Humbrol 56, Aluminum Dope). The air intakes’ interior became bright aluminum (Revell 99), the area around the jet nozzle was painted with Revell 91 (Iron metallic) and later treated with graphite for a dark metallic shine. The drop tanks were camouflaged, the Firestreaks became white so that they would stand out well and add to a certain vintage look.

 

The decals were a mix from various sources. The No. 20 Squadron badges and the Type D high-viz roundels on the wings were left over from an Airfix Hawker Hunter. The fuselage roundels came from an Italeri BAe Hawk sheet, IIRC. The bent fin flash, all the stencils as well as the serial code (which was puzzled together from two real serials and was AFAIK not allocated to any real RAF aircraft) came from an Xtradecal Supermarine Swift sheet. The individual red “B” letter came from a Matchbox A.W. Meteor night fighter.

 

Finally, the kit was sealed with matt acrylic varnish – I considered a glossy finish, since this was typical for RAF aircraft in the Fifties, but eventually just gave the radome a light shine.

  

Basically a simple project, and quickly done in just a couple of days. However, chrisonord’s great eye for similarities makes this “Tiger in disguise” a great fictional aircraft model with only little effort, it’s IMHO very convincing. And the RAF colors and markings suit the F11F very well.

+++ DISCLAIMER +++

Nothing you see here is real, even though the conversion or the presented background story might be based on historical facts. BEWARE!

  

Some background:

The Grumman Mohawk began as a joint Army-Marine program through the then-Navy Bureau of Aeronautics (BuAer), for an observation/attack plane that would outperform the light and vulnerable Cessna L-19 Bird Dog. In June 1956, the Army issued Type Specification TS145, which called for the development and procurement of a two-seat, twin turboprop aircraft designed to operate from small, unimproved fields under all weather conditions. It would be faster, with greater firepower, and heavier armor than the Bird Dog, which had proved very vulnerable during the Korean War.

 

The Mohawk's mission would include observation, artillery spotting, air control, emergency resupply, naval target spotting, liaison, and radiological monitoring. The Navy specified that the aircraft had to be capable of operating from small "jeep" escort class carriers (CVEs). The DoD selected Grumman Aircraft Corporation's G-134 design as the winner of the competition in 1957. Marine requirements contributed an unusual feature to the design: since the Marines were authorized to operate fixed-wing aircraft in the close air support (CAS) role, the mockup featured underwing pylons for rockets, bombs, and other stores, and this caused a lot of discord. The Air Force did not like the armament capability of the Mohawk and tried to get it removed. On the other side, the Marines did not want the sophisticated sensors the Army wanted, so when their Navy sponsors opted to buy a fleet oil tanker, they eventually dropped from the program altogether. The Army continued with armed Mohawks (and the resulting competence controversy with the Air Force) and also developed cargo pods that could be dropped from underwing hard points to resupply troops in emergencies.

 

In mid-1961, the first Mohawks to serve with U.S. forces overseas were delivered to the 7th Army at Sandhofen Airfield near Mannheim, Germany. Before its formal acceptance, the camera-carrying AO-1AF was flown on a tour of 29 European airfields to display it to the U.S. Army field commanders and potential European customers. In addition to their Vietnam and European service, SLAR-equipped Mohawks began operational missions in 1963 patrolling the Korean Demilitarized Zone.

 

Germany and France showed early interest in the Mohawk, and two OV-1s were field-tested by both nations over the course of several months. No direct orders resulted, though, but the German Bundesheer (Army) was impressed by the type’s performance and its capability as an observation and reconnaissance platform. Grumman even signed a license production agreement with the French manufacturer Breguet Aviation in exchange for American rights to the Atlantic maritime patrol aircraft, but no production orders followed.

 

This could have been the end of the OV-1 in Europe, but in 1977 the German government, primarily the interior ministry and its intelligence agency, the Bundesnachrichtendienst (BND), showed interest in a light and agile SIGINT/ELINT platform that could fly surveillance missions along the inner-German border to the GDR and also to Czechoslovakia. Beyond visual reconnaissance with cameras and IR sensors, the aircraft was to be specifically able to identify and locate secret radio stations that were frequently operated by Eastern Block agents (esp. by the GDR) all across Western Germany, but primarily close to the inner-German border due to the clandestine stations’ low power. The Bundeswehr already operated a small ELINT/ECM fleet, consisting of converted HFB 320 ‘Hansa’ business jets, but these were not suited for stealthy and inconspicuous low flight level missions that were envisioned, and they also lacked the ability to fly slowly enough to locate potential “radio nests”.

 

The pan and the objective were clear, but the ELINT project caused a long and severe political debate concerning the operator of such an aerial platform. Initially, the Bundesheer, who had already tested the OV-1, claimed responsibility, but the interior ministry in the form of the German customs department as well as the German police’s Federal Border Guard, the Bundesgrenzschutz and the Luftwaffe (the proper operator for fixed-wing aircraft within the German armed forces), wrestled for this competence. Internally, the debate and the project ran under the handle “Schimmelreiter” (literally “The Rider on the White Horse”), after a northern German legendary figure, which eventually became the ELINT system’s semi-official name after it had been revealed to the public. After much tossing, in 1979 the decision was made to procure five refurbished U.S. Army OV-1As, tailored to the German needs and – after long internal debates – operate them by the Luftwaffe.

 

The former American aircraft were hybrids: they still had the OV-1A’s original short wings, but already the OV-1D’s stronger engines and its internal pallet system for interchangeable electronics. The machines received the designation OV-1G (for Germany) and were delivered in early 1980 via ship without any sensors or cameras. These were of Western German origin, developed and fitted locally, tailored to the special border surveillance needs.

 

The installation and testing of the “Schimmelreiter” ELINT suite lasted until 1982. It was based on a Raytheon TI Systems emitter locator system, but it was locally adapted by AEG-Telefunken to the airframe and the Bundeswehr’s special tasks and needs. The system’s hardware was stowed in the fuselage, its sensor arrays were mounted into a pair of underwing nacelles, which occupied the OV-1’s standard hardpoints, allowing a full 360° coverage. In order to cool the electronics suite and regulate the climate in the internal equipment bays, the OV-1G received a powerful heat exchanger, mounted under a wedge-shaped fairing on the spine in front of the tail – the most obvious difference of this type from its American brethren. The exact specifications of the “Schimmelreiter” ELINT suite remained classified, but special emphasis was placed upon COMINT (Communications Intelligence), a sub-category of signals intelligence that engages in dealing with messages or voice information derived from the interception of foreign communications. Even though the “Schimmelreiter” suite was the OV-1Gs’ primary reconnaissance tool, the whole system could be quickly de-installed for other sensor packs and reconnaissance tasks (even though this never happened), or augmented by single modules, what made upgrades and mission specialization easy. Beyond the ELINT suite, the OV-1G could be outfitted with cameras and other sensors on exchangeable pallets in the fuselage, too. This typically included a panoramic camera in a wedge-shaped ventral fairing, which would visually document the emitter sensors’ recordings.

 

A special feature of the German OV-1s was the integration of a brand new, NATO-compatible “Link-16” data link system via a MIDS-LVT (Multifunctional Information Distribution System). Even though this later became a standard for military systems, the OV-1G broke the ground for this innovative technology. The MIDS was an advanced command, control, communications, computing and intelligence (C4I) system incorporating high-capacity, jam-resistant, digital communication links for exchange of near real-time tactical information, including both data and voice, among air, ground, and sea elements. Outwardly, the MIDS was only recognizable through a shallow antenna blister behind the cockpit.

 

Even though the OV-1Gs initially retained their former American uniform olive drab livery upon delivery and outfitting in German service, they soon received a new wraparound camouflage for their dedicated low-level role in green and black (Luftwaffe Norm 83 standard), which was better suited for the European theatre of operations. In Luftwaffe service, the OV-1Gs received the tactical codes 18+01-05 and the small fleet was allocated to the Aufklärungsgeschwader (AG) 51 “Immelmann”, where the machines formed, beyond two squadrons with RF-4E Phantom IIs, an independent 3rd squadron. This small unit was from the start based as a detachment at Lechfeld, located in Bavaria/Southern Germany, instead of AG 51’s home airbase Bremgarten in South-Western Germany, because Lechfeld was closer to the type’s typical theatre of operations along Western Germany’s Eastern borders. Another factor in favor of this different airbase was the fact that Lechfeld was, beyond Tornado IDS fighter bombers, also the home of the Luftwaffe’s seven HFB 320M ECM aircraft, operated by the JaBoG32’s 3rd squadron, so that the local maintenance crews were familiar with complex electronics and aircraft systems, and the base’s security level was appropriate, too.

 

With the end of the Cold War in 1990, the OV-1Gs role and field of operation gradually shifted further eastwards. With the inner-German Iron Curtain gone, the machines were now frequently operated along the Polish and Czech Republic border, as well as in international airspace over the Baltic Sea, monitoring the radar activities along the coastlines and esp. the activities of Russian Navy ships that operated from Kaliningrad and Saint Petersburg. For these missions, the machines were frequently deployed to the “new” air bases Laage and Holzdorf in Eastern Germany.

 

In American service, the OV-1s were retired from Europe in 1992 and from operational U.S. Army service in 1996. In Germany, the OV-1 was kept in service for a considerably longer time – with little problems, since the OV-1 airframes had relatively few flying hours on their clocks. The Luftwaffe’s service level for the aircraft was high and spare parts remained easy to obtain from the USA, and there were still OV-1 parts in USAF storage in Western German bases.

 

The German HFB 320M fleet was retired between 1993 and 1994 and, in part, replaced by the Tornado ECR. At the same time AG 51 was dissolved and the OV-1Gs were nominally re-allocated to JaboG 32/3. With this unit the OV-1Gs remained operational until 2010, undergoing constant updates and equipment changes. For instance, the machines received in 1995 a powerful FLIR sensor in a small turret in the aircraft’s nose, which improved the aircraft’s all-weather reconnaissance capabilities and was intended to spot hidden radio posts even under all-weather/night conditions, once their signal was recognized and located. The aircrafts’ radio emitter locator system was updated several times, too, and, as a passive defensive measure against heat-guided air-to-air missiles/MANPADS, an IR jammer was added, extending the fuselage beyond the tail. These machines received the suffix “Phase II”, even though all five aircraft were updated the same way.

Reports that the OV-1Gs were furthermore retrofitted with the avionics to mount and launch AIM-9 Sidewinder AAMs under the wing tips for self-defense remained unconfirmed, even more so because no aircraft was ever seen carrying arms – neither the AIM-9 nor anything else. Plans to make the OV-1Gs capable of carrying the Luftwaffe’s AGM-65 Maverick never went beyond the drawing board, either. However, BOZ chaff/flare dispenser pods and Cerberus ECM pods were occasionally seen on the ventral pylons from 1998 onwards.

 

No OV-1G was lost during the type’s career in Luftwaffe service, and after the end of the airframes’ service life, all five German OV-1Gs were scrapped in 2011. There was, due to worsening budget restraints, no direct successor, even though the maritime surveillance duties were taken over by Dornier Do 228/NGs operated by the German Marineflieger (naval air arm).

  

General characteristics:

Crew: Two: pilot, observer/systems operator

Length: 44 ft 4 in (13.53 m) overall with FLIR sensor and IR jammer

Wingspan: 42 ft 0 in (12.8 m)

Height: 12 ft 8 in (3.86 m)

Wing area: 330 sq. ft (30.65 m²)

Empty weight: 12,054 lb (5,467 kg)

Loaded weight: 15,544 lb (7,051 kg)

Max. takeoff weight: 18,109 lb (8,214 kg)

 

Powerplant:

2× Lycoming T53-L-701 turboprops, 1,400 shp (1,044 kW) each

 

Performance:

Never exceed speed: 450 mph (390 knots, 724 km/h)

Maximum speed: 305 mph (265 knots, 491 km/h) at 10,000 ft (3,050 m)

Cruise speed: 207 mph (180 knots, 334 km/h) (econ cruise)

Stall speed: 84 mph (73 knots, 135 km/h)

Range: 944 mi (820 nmi, 1,520 km) (SLAR mission)

Service ceiling: 25,000 ft (7,620 m)

Rate of climb: 3,450 ft/min (17.5 m/s)

 

Armament:

A total of eight external hardpoints (two ventral, three under each outer wing)

for external loads; the wing hardpoints were typically occupied with ELINT sensor pods, while the

ventral hardpoints frequently carried 300 l drop tanks to extend loiter time and range;

Typically, no offensive armament was carried, even though bombs or gun/missile pods were possible.

  

The kit and its assembly:

This build became a submission to the “Reconnaissance” Group Build at whatifmodellers.com in July 2021, and it spins further real-world events. Germany actually tested two OV-1s in the Sixties (by the German Army/Bundesheer, not by the air force), but the type was not procured or operated. The test aircraft carried a glossy, olive drab livery (US standard, I think) with German national markings.

However, having a vintage Hasegawa OV-1A in the stash, I wondered what an operational German OV-1 might have looked like, especially if it had been operated into the Eighties and beyond, in the contemporary Norm 83 paint scheme? This led to this purely fictional OV-1G.

 

The kit was mostly built OOB, and the building experience was rather so-so – after all, it’s a pretty old mold/boxing (in my case the Hasegawa/Hales kit is from 1978, the mold is from 1968!). Just a few things were modified/added in order to tweak the standard, short-winged OV-1A into something more modern and sophisticated.

 

When searching for a solution to mount some ELINT sensor arrays, I did not want to copy the OV-1B’s characteristic offset, ventral SLAR fairing. I rather settled for the late RV-1D’s solution with sensor pods under the outer wings. Unfortunately, the OV-1A kit came with the type’s original short wings, so that the pods had to occupy the inner underwing pair of hardpoints. The pods were scratched from square styrene profiles and putty, so that they received a unique look. The Mohawk’s pair of ventral hardpoints were mounted, but – after considering some drop tanks or an ECM pod there - left empty, so that the field of view for the ventral panoramic camera would not be obscured.

 

Other small additions are some radar warning sensor bumps on the nose, some extra antennae, a shallow bulge for the MIDS antenna on the spine, the FLIR turret on the nose (with parts from an Italeri AH-1 and a Kangnam Yak-38!), and I added a tail stinger for a retrofitted (scratched) IR decoy device, inspired by the American AN/ALG-147. This once was a Matchbox SNEB unguided missile pod.

  

Painting and markings:

For the intended era, the German Norm 83 paint scheme, which is still in use today on several Luftwaffe types like the Transall, PAH-2 or CH-53, appeared like a natural choice. It’s a tri-color wraparound scheme, consisting of RAL 6003 (Olivgrün), FS 34097 (Forest Green) and RAL 7021 (Teerschwarz). The paints I used are Humbrol 86 (which is supposed to be a WWI version of RAL 6003, it lacks IMHO yellow but has good contrast to the other tones), Humbrol 116 and Revell 9. The pattern itself was adapted from the German Luftwaffe’s Dornier Do 28D “Skyservants” with Norm 83 camouflage, because of the type’s similar outlines.

 

A black ink washing was applied for light weathering, plus some post-shading of panels with lighter shades of the basic camouflage tones for a more plastic look. The cockpit interior was painted in light grey (Humbrol 167), while the landing gear and the interior of the air brakes became white. The scratched SLAR pods became light grey, with flat di-electric panels in medium grey (created with decal material).

The cockpit interior was painted in a rather light grey (Humbrol 167), the pilots received typical olive drab Luftwaffe overalls, one with a white “bone dome” and the other with a more modern light grey helmet.

 

The decals were improvised. National markings and tactical codes came from TL Modellbau sheets, the AG 51 emblems were taken from a Hasegawa RF-4E sheet. The black walkways were taken from the Mohak’s OOB sheet, the black de-icer leading edges on wings and tail were created with generic black decal material. Finally, the model was sealed with a coat of matt acrylic varnish (Italeri).

  

An interesting result, and the hybrid paint scheme with the additional desert camouflage really makes the aircraft an unusual sight, adding to its credibility.

+++ DISCLAIMER +++

Nothing you see here is real, even though the conversion or the presented background story might be based on historical facts. BEWARE!

  

Some background:

The McDonnell Douglas (now Boeing) T-45 Goshawk was a highly modified version of the BAe Hawk land-based training jet aircraft. Manufactured by McDonnell Douglas (now Boeing) and British Aerospace (now BAe Systems), the T-45 was used by the United States Navy and the United States Marine Corps (USMC) as an aircraft carrier-capable trainer.

The Goshawk's origins began in the mid-1970s, when the US Navy began looking for a single aircraft replacement for both its T-2 and TA-4 jet trainers. The US Navy started the VTXTS advanced trainer program in 1978. Several companies made submissions, e. g. North American or Northrop/Vought. Due to the size of the potential contract, European companies made submissions, too, including a navalized Alpha Jet from Dassault/Dornier and a fully carrier-capable version of the BAe Hawk Mk.60, mutually proposed by British Aerospace (BAe) and McDonnell Douglas (MDC). The latter eventually won the competition and BAe and MDC were awarded the T-45 contract in 1981.

 

The Hawk had not been designed for carrier operations and numerous modifications were required to make it suitable for use on carriers. These included improvements to the low-speed handling characteristics and a reduction in the approach speed. It was found that the aircraft was apt to stall at the low approach speed required. Modifications were designed by BAe in England; most notably a simple slat system was devised, operated by an actuator and linkage mechanism to fit into the small space available. Strakes were also added on the fuselage to improve airflow. Other changes were a strengthened airframe, a more robust and wider landing gear with a two-wheel nose landing gear, a catapult tow bar attachment and an arresting hook. The modified aircraft was christened “Goshawk”, flew in 1988 for the first time and became operational in 1991.

 

Beyond being a naval trainer the T-45 was also adapted for first-line duty with strike capabilities, in the form of the OA-45 for the USMC. The role of this aircraft dated back to the Vietnam War when twenty-three A-4 two-seaters were converted into OA-4Ms for “FastFAC” (Fast Forward Air Controller) missions, in order to control interdiction sorties dedicated to shaping the battlefield for future operations. Basically, the OA-4M was a TA-4F equipped with A-4M electronics. The most visible and characteristic change was the fitting of the A-4M’s dorsal electronics hump, neatly faired into the rear of the two-seat canopy. The nose sensor group of the OA-4M was basically the same as that of the A-4M, but the Angle/Rate Bombing system was not installed as it would not be needed.

 

When the T-45 was introduced in the early Nineties, the USMCs OA-4Ms had reached the end of their service life and the USMC started looking for a replacement, wanting a comparable, light and fast fixed-wing aircraft. The USMC did not accept the LTV A-7 as an A-4 replacement (even though a two-seater version was available), because it was already dated, too, and not part of the USMC inventory. The USMC's A-4Ms were supposed to be replaced by the VTOL AV-8 by the mid-nineties, but the AV-8, even as a two-seater, was deemed unsuitable for FFAC duties. The new T-45 looked like a good and economical alternative with future potential, since the airframe was brand new and the type's infrastructure was fully established, so that a small number of specialized aircraft could easily be supported without much extra cost.

 

With fresh experience from the 1st Gulf War in 1990-91 the decision was made to buy 25 extra T-45A airframes and convert them to OA-45A standard. Most important change were modified wings, using structures and systems from the BAe Hawk 100 series. While the T-45 only had two underwing and a single ventral hardpoint, the OA-45A featured a total of seven: four underwing and one ventral hardpoints, plus wingtip stations for defensive air-to-air missiles. Upgraded avionics allowed the deployment of a wide range of external stores, including air-to-ground missiles and rocket launchers, a reconnaissance pod, retarded and free-fall bombs of up to 1,000 pounds (450 kg) caliber, runway cratering, anti-personnel and light armor bombs, cluster bombs, practice bombs as well as external fuel tanks and ECM pods. This was a vital asset, since Desert Storm had proved that FFAC aircraft had to have an offensive capability to handle targets of opportunity on their own, when no air assets to control were available. A total ordnance load of up to 6,800 lb (3,085 kg) was possible, even though the aircraft was not supposed to play an offensive role and rather act from a distance, relying on its small size and agility.

 

Communication modifications for the FastFAC role included a KY-28 secure voice system, an ARC-159 radio and an ARC-114 VHF radio. Similar to the Skyhawk, a hump behind the cockpit had to be added to make room for the additional electronic equipment and a heat exchanger. Other additions were a continuous-wave Doppler navigation radar under a shallow ventral radome underneath the cockpit, a ground control bombing system, an APN-194 altimeter, an ALR-45 radar warning suite, a retrofitted, fixed midair refueling probe and cockpit armor plating that included Kevlar linings on the floor and the lower side walls as well as externally mounted armor plates for the upper areas.

 

VMA-131 of Marine Aircraft Group 49 (the Diamondbacks) retired its last four OA-4Ms on 22 June 1994, and the new OA-45A arrived just in time to replace the venerable Skyhawk two-seaters in the FastFAC role. Trainer versions of the Skyhawk remained in Navy service, however, finding a new lease on life with the advent of "adversary training". OA-45A deliveries were finished in 1996 and the 25 aircraft were distributed among the newly established Marine Aviation Logistics Squadron (MALS, formerly Headquarters & Maintenance Squadron/H&MS) 12 & 13. The USMC crews soon nicknamed their new mounts "GosHog", to underlöine ist offensive capabilities and to set themselves apart from the USN's "tame" trainers. Even though thos name was never officially approved it caught on quickly.

 

After initial experience with the new aircraft and in the wake of technological advances, the USMC decided to upgrade the OA-45As in 2000 to improve its effectiveness and interaction capabilities with ground troops. This primarily resulted in the addition of a forward-looking infrared camera laser in the aircraft’s nose section, which enabled the aircraft to execute all-weather/night reconnaissance and to illuminate targets for laser-guided infantry shells or ordnance launched by the OA-45 itself or by other aircraft. Through this measure the OA-45 became capable of carrying and independently deploying light laser-guided smart weapons like the GBU-12 and -16 “Paveway II” glide bombs or the laser-guided AGM-65E “Maverick” variant. The update was gradually executed during regular overhauls in the course of 2001 and 2002 (no new airframes were built/converted), the modified machines received the new designation OA-45B.

 

After this update phase, the OA-45Bs were deployed in several global conflicts and saw frequent use in the following years. For instance, MALS 13 used its OA-45Bs operationally for the first time in October 2002 when the squadron was tasked with providing support to six AV-8B Harrier aircraft in combat operations in Afghanistan during Operation Enduring Freedom. This mission lasted until October 2003, four aircraft were allocated and one OA-45B was lost during a landing accident.

On 15 January 2003, MALS 13 embarked 205 Marines and equipment aboard the USS Bonhomme Richard in support of combat operations in Southwest Asia during Operation Southern Watch. Four OA-45Bs successfully supported these troops from land bases, marking targets and flying reconnaissance missions.

Furthermore, six MALS 13 OA-45Bs took actively part in Operation Iraqi Freedom from Al Jaber Air Base, Kuwait, and An Numiniyah Expeditionary Air Field, Iraq, where the aircraft worked closely together with the advancing ground troops of the USMC’s 15th Marine Expeditionary Unit. They successfully illuminated targets for US Navy fighter bombers, which were launched from USS Abraham Lincoln (CVN-72) in the Persian Gulf, and effectively guided these aircraft to their targets. Two OA-45Bs were lost during this conflict, one through enemy MANPADS, the other through friendly AA fire. In late May 2003 the surviving machines and their crews returned to MCAS Yuma.

 

On 16 March 2007, the 200th T-45 airframe was delivered to the US Navy. From this final batch, six airframes were set aside and modified into OA-45Bs in order to fill the losses over the past years.

Later T-45 production aircraft were built with enhanced avionics systems for a heads-up display (HUD) and glass cockpit standard, while all extant T-45A aircraft were eventually converted to a T-45C configuration under the T-45 Required Avionics Modernization Program (T-45 RAMP), bringing all aircraft to same HUD plus glass cockpit standard. These updates, esp. concerning the cockpit, were introduced to the OA-45Bs, too, and they were re-designated again, now becoming OA-45Cs, to reflect the commonality with the Navy’s Goshawk trainers. Again, these modifications were gradually introduced in the course of the OA-45s’ normal maintenance program.

 

In 2007, an engine update of the whole T-45 fleet, including the OA-45s, with the Adour F405-RR-402 was considered. This new engine was based on the British Adour Mk 951, designed for the latest versions of the BAe Hawk and powering the BAe Taranis and Dassault nEUROn UCAV technology demonstrators. The Adour Mk 951 offered 6,500 lbf (29 kN) thrust and up to twice the service life of the F405-RR-401. It featured an all-new fan and combustor, revised HP and LP turbines, and introduced Full Authority Digital Engine Control (FADEC). The Mk 951 was certified in 2005, the F405-RR-402 derived from it was certified in 2008, but it did not enter service due to funding issues, so that this upgrade was not carried out.

 

The final delivery of the 246th T-45 airframe took place in November 2009, and both T-45 and the OA-45 "GosHog" are supposed to remain in service until 2035.

  

General characteristics:

Crew: 2 (pilot, observer)

Length: 39 ft 4 in (11.99 m)

Wingspan: 30 ft 10 in (9.39 m)

Height: 13 ft 5 in (4.08 m)

Wing area: 190.1 ft² (17.7 m²)

Empty weight: 10,403 lb (4,460 kg)

Max. takeoff weight: 14,081 lb (6,387 kg)

 

Powerplant:

1× Rolls-Royce Turbomeca F405-RR-401 (Adour) non-afterburning turbofan with 5,527 lbf (26 kN)

 

Performance:

Maximum speed: Mach 2 (2,204 km/h (1,190 kn; 1,370 mph) at high altitude

Combat radius: 800 km (497 mi, 432 nmi)

Ferry range: 3,200 km (1,983 mi) with drop tanks

Service ceiling: 15,240 m (50,000 ft)

Wing loading: 283 kg/m² (58 lb/ft²)

Thrust/weight: 0.97

Maximum g-load: +9 g

 

Armament:

No internal gun; seven external hardpoints (three on each wing and one under fuselage)

for a wide range of ordnance of up to 6,800 lb (3,085 kg), including up to six AIM-9 Sidewinder for

self-defense, pods with unguided rockets for target marking or ECM pods, but also offensive weapons

of up to 1.000 lb (454 kg) weight, including iron/cluster bombs and guided AGM-65, GBU-12 and -16.

  

The kit and its assembly:

This fictional T-45 variant is actually the result of a long idea evolution, and simply rooted in the idea of a dedicated OA-4M replacement for the USMC; in real life, the FFAC role has been transferred to F-18 two-seaters, though, but the T-45 appeared like a sound alternative to me.

 

There's only one T-45 kit available, a dubious T-45A from Italeri with poor wings and stabilizers. Wolfpack also offers a T-45, but it’s just a re-boxing of the Italeri kit with some PE parts and a price tag twice as big – but it does not mend the original kit’s issues… After reading the A-4 Skyhawk book from the French "Planes & Pilots" series, I was reminded of the USMC's special OA-4M FAC two-seaters (and the fact that it is available in kit form from Italeri and Hasegawa), and, cross-checking the real-world timeline of the T-45, I found that it could have been a suitable successor. The ide of the USMC’s OA-45 was born! :D

 

Building-wise the Italeri T-45 remained close to OOB, even though I transplanted several parts from an Italeri BAe Hawk Mk. 100 to create a different look. I modified the nose with the Mk. 100’s laser fairing and added some radar warning sensor bumps. This transplantation was not as easy as it might seem because the T-45’s nose is, due to the different and more massive front landing gear quite different from the Hawk’s. Took some major PSR to integrate the laser nose.

An ALR-45 “hot dog” fairing from a late A-4M (Italeri kit) was added to the fin, together with a small styrene wedge extending the fin’s leading edge. This small detail markedly changes the aircraft’s look. I furthermore added a refueling probe, scratched from coated wire and some white glue, as well as a low “camel back” fairing behind the cockpit, created from a streamlined bomb half with air outlets for an integrated heat exchanger. Blade antennae were relocated and added. A shallow bump for the Doppler radar was added under the fuselage behind the landing gear well – left over from an Airfix A-4B (from an Argentinian A-4P, to be correct, actually a dorsal fairing).

 

On the wings, a tailored pair of pylons and wing tip launch rails from the Italeri BAe Hawk Mk. 100 kit were added, too, as well as the donor kit’s pair of Sidewinders. The rest of the ordnance consists of drop tanks and LAU-19 pods for target marking missiles. The tanks were taken from the Hawk Mk. 100 kit, too, the rocket launchers came from an Italeri NATO aircraft weapons set. The centerline position carries an ALQ-131 ECM pod from a Hasegawa US aircraft weapons set on a pylon from the scrap box.

  

Painting and markings:

The low-viz idea prevailed, since I had some leftover OA-4M decals from Italeri kits in store, as well as some other suitable low-viz decals from a Revell A-4F kit. However, an all-grey livery was IMHO not enough, and when I came across a picture of a USN low-viz A-7E with an improvised desert camouflage in sand and reddish brown applied over the grey (even partly extending over its markings) from Operation Iraqi Freedom, I had that extra twist that would set the OA-45 apart. MALS-13 was chosen as operator because I had matching codes, and, as another benefit, the unit had actually been deployed overseas during the 2003 Iraq War, so that the whif’’s time frame was easily settled, adding to its credibility.

 

The livery was built up just like on the real aircraft: on top of a basic scheme in FS 36320 and 36375 (Humbrol 128 and 127) with a slightly darker anti-glare panel in front of the cockpit (FS 35237, I used Revell 57 as a slightly paler alternative) I applied the low-viz marking decals, which were protected with a coat of acrylic varnish. Next, additional desert camouflage was added with dry-brushed sand and millitary brown (supposedly FS 33711 and 30400 in real life, I used, after consulting pictures of aircraft from both Gulf Wars, Humbrol 103 (Cream) and 234 (Dark Flesh). They were applied with a kind of a dry-brushing technique, for a streaky and worn look, leaving out the codes and other markings. The pattern itself was inspired by an USMC OV-10 Bronco in desert camouflage from the 1st Gulf War.

On top of that a black ink washing was applied. Once things had thoroughly dried over night, I wet-sanded the additional desert camouflage away, carefully from front to back, so that the edges became blurred and the underlying grey became visible again.

 

The cockpit interior was painted in standard Dark Gull Grey (Humbrol 140), while the air intakes and the landing gear became white, the latter with red trim on the covers’ edges – just standard. Finally, the model was sealed with a coat of matt acrylic varnish (Italeri).

  

The upgraded T-45 is an interesting result. The add-ons suit the aircraft, which already looks sturdier than its land-based ancestor, well. The improvised desert paint scheme with the additional two-tone camouflage over the pale grey base really makes the aircraft an unusual sight, adding to its credibility.

Hardware-wise I am really happy how the added dorsal hump blends into the overall lines – in a profile view it extends the canopy’s curve and blends into the fin, much like the A-4F/M’s arrangement. And the modified fin yields a very different look, even though not much was changed. The T-45 looks much beefier now, and from certain angles really reminds of the OA-4M and sometimes even of a diminutive Su-25?

Some background:

The VF-1 was developed by Stonewell/Bellcom/Shinnakasu for the U.N. Spacy by using alien Overtechnology obtained from the SDF-1 Macross alien spaceship. It was preceded into production by an aerodynamic proving version of its airframe, the VF-X. Unlike all later VF vehicles, the VF-X was strictly a jet aircraft, built to demonstrate that a jet fighter with the features necessary to convert to Battroid mode was aerodynamically feasible.

 

After the VF-X's testing was finished, an advanced concept atmospheric-only prototype, the VF-0 Phoenix, was flight-tested from 2005 to 2007 and briefly served as an active-duty fighter from 2007 to the VF-1's rollout in late 2008, while the bugs were being worked out of the full-up VF-1 prototype (VF-X-1).

 

The space-capable VF-1's combat debut was on February 7, 2009, during the Battle of South Ataria Island - the first battle of Space War I, and was the mainstay fighter of the U.N. Spacy for the entire conflict. Introduced in 2008, the VF-1 would be out of frontline service just five years later.

 

The VF-1 proved to be an extremely capable craft, successfully combating a variety of Zentraedi mecha even in most sorties, which saw UN Spacy forces significantly outnumbered. The versatility of the Valkyrie design enabled the variable fighter to act as both large-scale infantry and as air/space superiority fighter. The signature skills of U.N. Spacy ace pilot Maximilian Jenius exemplified the effectiveness of the variable systems as he near-constantly transformed the Valkyrie in battle to seize advantages of each mode as combat conditions changed from moment to moment.

The basic VF-1 was deployed in four minor variants (designated A, D, J, and S) with constant updates and several sub-variants during its long and successful career. Its success was increased by the GBP-1S "Armored" Valkyrie and FAST Pack "Super" Valkyrie weapon systems, the latter enabling the fighter to operate in space.

After the end of Space War I, the VF-1A continued to be manufactured both in the Sol system (notably on the Lunar facility Apollo Base) and throughout the UNG space colonies. Although the VF-1 would eventually be replaced as the primary VF of the UN Spacy by the more capable, but also much bigger, VF-4 Lightning III in 2020, a long service record and continued production after the war proved the lasting worth of the design.

 

One notable operator of the VF-1 was the U.N. Spacy's Zentraedi Fleet, namely SVF-789, which was founded in 2012 as a cultural integration and training squadron with two flights of VF-1 at Tefé in Brazil. This mixed all-Zentraedi/Meltraedi unit was the first in the UN Spacy’s Zentraedi Fleet to be completely equipped with the 1st generation Valkyrie (other units, like SVF-122, which was made up exclusively from Zentraedi loyalists, kept a mixed lot of vehicles).

 

SVF-789’s flight leaders and some of its instructors were all former Quadrono Battalion aces (under the command of the famous Milia Fallyna, later married with aforementioned Maximilian Jenius), e. g. the Meltraedi pilot Taqisha T’saqeel who commanded SVF-789’s 3rd Flight.

 

Almost all future Zentraedi and Meltradi pilots for the U.N. Spacy received their training at Tefé, and the squadron was soon expanded to a total of five flights. During this early phase of the squadron's long career the VF-1s carried a characteristic dark-green wrap-around scheme, frequently decorated with colorful trim, reflecting the unit’s Zentraedi/Meltraedi heritage (the squadron’s motto and title “Dar es Carrack” meant “Victory is everywhere”) and boldly representing the individual flights.

 

In late 2013 the unit embarked upon Breetai Kridanik’s Nupetiet-Vergnitzs-Class Fleet Command Battleship, and the machines received a standard all-grey livery, even though some typical decoration (e. g. the squadron code in Zentraedi symbols) remained.

 

When the UN Spacy eventually mothballed the majority of its legacy Zentraedi ships, the unit was re-assigned to the Tokugawa-class Super Dimensional Carrier UES Xerxes. In 2022, SVF-789 left the Sol System as part of the Pioneer Mission. By this time it had been made part of the Expeditionary Marine Corps and re-equipped with VAF-6 Alphas.

 

The VF-1 was without doubt the most recognizable variable fighter of Space War I and was seen as a vibrant symbol of the U.N. Spacy even into the first year of the New Era 0001 in 2013. At the end of 2015 the final rollout of the VF-1 was celebrated at a special ceremony, commemorating this most famous of variable fighters.

 

The VF-1 Valkryie was built from 2006 to 2013 with a total production of 5,459 VF-1 variable fighters with several variants (VF-1A = 5,093, VF-1D = 85, VF-1J = 49, VF-1S = 30, VF-1G = 12, VE-1 = 122, VT-1 = 68) and ongoing modernization programs like the “Plus” MLU update that incorporated stronger engines and avionics from the VF-1’s successor, the VF-4 (including the more powerful radar, IRST sensor and a laser designator/range finder). These updates later led to the VF-1N, P an X variants.

However, the fighter remained active in many second line units and continued to show its worthiness years later, e. g. through Milia Jenius who would use her old VF-1 fighter in defense of the colonization fleet - 35 years after the type's service introduction!

 

General characteristics:

Equipment Type: all-environment variable fighter and tactical combat battroid

Government: U.N. Spacy, U.N. Navy, U.N. Space Air Force

 

Accommodation: pilot only in Marty & Beck Mk-7 zero/zero ejection seat

Dimensions:

Fighter Mode:

Length 14.23 meters

Wingspan 14.78 meters (fully extended)

Height 3.84 meters

Battroid Mode:

Height 12.68 meters

Width 7.3 meters

Length 4.0 meters

Empty weight: 13.25 metric tons;

Standard T-O mass: 18.5 metric tons;

MTOW: 37.0 metric tons

 

Powerplant:

2x Shinnakasu Heavy Industry/P&W/Roice FF-2008 thermonuclear reaction turbine engines, output 650 MW each, rated at 11,500 kg in standard or in overboost (225.63 kN x 2)

4 x Shinnakasu Heavy Industry NBS-1 high-thrust vernier thrusters (1 x counter reverse vernier thruster nozzle mounted on the side of each leg nacelle/air intake, 1 x wing thruster roll control system on each wingtip);

18 x P&W LHP04 low-thrust vernier thrusters beneath multipurpose hook/handles

Performance:

Battroid Mode: maximum walking speed 160 km/h

Fighter Mode: at 10,000 m Mach 2.71; at 30,000+ m Mach 3.87

g limit: in space +7

Thrust-to-weight ratio: empty 3.47; standard T-O 2.49; maximum T-O 1.24

 

Design features:

3-mode variable transformation; variable geometry wing; vertical take-off and landing; control-configurable vehicle; single-axis thrust vectoring; three "magic hand" manipulators for maintenance use; retractable canopy shield for Battroid mode and atmospheric reentry; option of GBP-1S system, atmospheric-escape booster, or FAST Pack system

Transformation:

Standard time from Fighter to Battroid (automated): under 5 sec.

Minimum time from Fighter to Battroid (manual): 0.9 sec.

Armament:

2x internal Mauler RÖV-20 anti-aircraft laser cannon, firing 6,000 pulses per minute

1x Howard GU-11 55 mm three-barrel Gatling gun pod with 200 rds fired at 1,200 rds/min

4 x underwing hard points for a wide variety of ordnance, including

- 12x AMM-1 hybrid guided multipurpose missiles (3/point), or

- 12x MK-82 LDGB conventional bombs (3/point), or

- 6x RMS-1 large anti-ship reaction missiles (2/outboard point, 1/inboard point), or

- 4x UUM-7 micro-missile pods (1/point), each carrying 15x Bifors HMM-01 micro-missiles,

or a combination of above load-outs

Optional Armament:

Shinnakasu Heavy Industry GBP-1S ground-combat protector weapon system, or

Shinnakasu Heavy Industry FAST Pack augmentative space weapon system

  

The kit and its assembly:

The second vintage 1:100 ARII VF-1 as a part of a Zentraedi squadron series, the canonical SVF-789. This one was inspired by a profile of such a machine in the “Macross Variable Fighter Master File: VF-1 Valkyrie Part 1” Art Book – true robot porn and full of valuable detail and background material for anyone who’d consider building a VF-1.

 

The SVF-789 machine shown in the book is a simple VF-1A, but with Zentraedi language markings and in a rather unusual livery in all dark green, yellow and black trim and grey low-viz roundels. While this does IMHO not really look sexy, I found the idea of a squadron, manned by former (alien) enemies very interesting. And so I took up the idea and started fleshing it out – including the idea of SVF-789’s initial base deep in the Amazonian jungle (justifying somehow the all-green livery!?).

 

This second build was to represent a flight leader’s aircraft, and consequently the basis is a VF-1J kit (which only differs outwardly through the head). In order to set the machine a little more apart I decided to incorporate some “Plus” program updates, including a different nose tip for the updated radar and two small fairings for IRST and laser designator sensors above and below the nose section, respectively. The fins’ tips were also modified – they were elongated a little through styrene sheet replacements.

This update is a bit early for the official Macross timeline, but I just wanted more than a standard J Valkyrie in a more exotic paint scheme.

 

Otherwise, this VF-1J fighter kit was built OOB, with the landing gear tucked up and the usual additions of some blade antennae, a pilot figure and a custom display stand in/under the ventral cannon pod.

The ordnance is non-standard, though; in this case the aircraft received two pairs of air-to-ground missiles (actually some misshapen Soviet AAMs from the Academy MiG-23 kit – either very fat R-60 ‘Aphid’ AAMs or very poor renditions of vintage K-6 ‘Alkali’ missiles?) inboards and four AMM-1 missiles on the outer pylons, with the lowest missile replaced by scratched ECM and chaff dispenser pods. The gun pod was also modified with a new nozzle, with parts from a surplus AMM-1 missile – also inspired by a source book entry.

  

Painting and markings:

This was planned to be a more exotic or extravagant interpretation of the profile from the book, which was already used as a guideline for the VF-1A build. The overall design of an all-green livery with a white nose tip as basis was kept, together with yellow trim on wings, fins and the stabilizer fins on the Valkyrie’s legs. The VF-1A already deviated from this slightly, but now I wanted something more outstanding – a bold flight leader’s mount.

 

Zentraedi vehicles tend to be rather colorful, so the tones I chose for painting were rather bright. For instance, the initial idea for the green was FS 34079, a tone which also comes close to the printed profile in the book. But it looked IMHO too militaristic, or too little anime-esque, so I eventually settled for something brighter and used Humbrol 195 (called Dark Satin Green, but it’s actually RAL 6020, Chromoxyd Grün, a color used on German railway wagons during and after WWII), later shaded with black ink for the engravings and Humbrol 76 (Uniform Green) for highlights.

The nose became pure white, the leading edge trim was painted with Revell 310 (Lufthansa Gelb, RAL 1028), a deep and rich tone that stands out well from the murky green.

 

In order to set this J Valkyrie apart from the all-dark green basic VF-1As, I added two bright green tones and a light purple as flight color: Humbrol 36 (called Pastel Green, but it’s actually very yellow-ish), 38 (Lime) and Napoleonic Violet from ModelMaster’s Authentic Line, respectively. 36 was applied to the lower legs and around the cockpit section, including the spinal fairing with the air brake. The slightly darker 38 was used on the wings and fins as well as for the fuselage’s and wings’ underside. On top of the wings and the inner and outer fins, the surfaces were segmented, with the dark green as basic color.

As an additional contrast, the head, shoulder guards and additional trim highlights on the legs as well as for a double chevron on the breast plate were painted in the pale purple tone. A sick color combination, but very Zentraedi/Meltraedi-esque!

 

The cockpit interior was, according to Macross references, painted in Dark Gull Grey. The seat received brown cushions and the pilot figure was turned into a micronized Meltraedi (yes, the fictional pilot Taqisha T’saqeel is to be female) with a colorful jumpsuit in violet and white, plus a white and red helmet – and bright green skin! The gun pod became dark blue (Humbrol 112, Field Blue), the AMM-1 missiles received a pale grey livery while the air-to-ground missiles and the chaff dispenser became olive drab. As an additional contrast, the ECM pod became white. A wild mix of colors!

 

This was even enhanced through U.N. Spacy roundels in standard full color – their red really stands out. The squadron emblem/symbol on the fin was painted with a brush, but in this case in a smaller variant and with two USN/USAF style code letters for the home basis added.

Since I can not print white letters onto clear decal sheet at home, the aircraft’s tactical code ‘300’ was created with letters from the human alphabet. A simplification and deviation from the original concept, but I found the only alternative of painting tiny and delicate Zentraedi codes by brush and hand just to be too risky.

 

Finally, the kit was sealed with a sheen acrylic varnish – with the many, contrasting colors a pure matt finish somehow did not appear right.

  

Building was relatively simple, just the rhinoplasty was a little tricky – a very subtle modification, though, but the pointed and slightly deeper nose changed the VF-1’s look. The standard Zentraedi-style VF-1 of SVF-789 already looked …different, but this one is … bright, if not challenging to the naked eye. Anyway, there’s more in the creative pipeline from the Zentraedi unit – this aircraft’s pilot in the form of a modified resin garage kit.

Colosseum

Following, a text, in english, from the Wikipedia the Free Encyclopedia:

The Colosseum, or the Coliseum, originally the Flavian Amphitheatre (Latin: Amphitheatrum Flavium, Italian Anfiteatro Flavio or Colosseo), is an elliptical amphitheatre in the centre of the city of Rome, Italy, the largest ever built in the Roman Empire. It is considered one of the greatest works of Roman architecture and Roman engineering.

Occupying a site just east of the Roman Forum, its construction started between 70 and 72 AD[1] under the emperor Vespasian and was completed in 80 AD under Titus,[2] with further modifications being made during Domitian's reign (81–96).[3] The name "Amphitheatrum Flavium" derives from both Vespasian's and Titus's family name (Flavius, from the gens Flavia).

Capable of seating 50,000 spectators,[1][4][5] the Colosseum was used for gladiatorial contests and public spectacles such as mock sea battles, animal hunts, executions, re-enactments of famous battles, and dramas based on Classical mythology. The building ceased to be used for entertainment in the early medieval era. It was later reused for such purposes as housing, workshops, quarters for a religious order, a fortress, a quarry, and a Christian shrine.

Although in the 21st century it stays partially ruined because of damage caused by devastating earthquakes and stone-robbers, the Colosseum is an iconic symbol of Imperial Rome. It is one of Rome's most popular tourist attractions and still has close connections with the Roman Catholic Church, as each Good Friday the Pope leads a torchlit "Way of the Cross" procession that starts in the area around the Colosseum.[6]

The Colosseum is also depicted on the Italian version of the five-cent euro coin.

The Colosseum's original Latin name was Amphitheatrum Flavium, often anglicized as Flavian Amphitheater. The building was constructed by emperors of the Flavian dynasty, hence its original name, after the reign of Emperor Nero.[7] This name is still used in modern English, but generally the structure is better known as the Colosseum. In antiquity, Romans may have referred to the Colosseum by the unofficial name Amphitheatrum Caesareum; this name could have been strictly poetic.[8][9] This name was not exclusive to the Colosseum; Vespasian and Titus, builders of the Colosseum, also constructed an amphitheater of the same name in Puteoli (modern Pozzuoli).[10]

The name Colosseum has long been believed to be derived from a colossal statue of Nero nearby.[3] (the statue of Nero itself being named after one of the original ancient wonders, the Colossus of Rhodes[citation needed]. This statue was later remodeled by Nero's successors into the likeness of Helios (Sol) or Apollo, the sun god, by adding the appropriate solar crown. Nero's head was also replaced several times with the heads of succeeding emperors. Despite its pagan links, the statue remained standing well into the medieval era and was credited with magical powers. It came to be seen as an iconic symbol of the permanence of Rome.

In the 8th century, a famous epigram attributed to the Venerable Bede celebrated the symbolic significance of the statue in a prophecy that is variously quoted: Quamdiu stat Colisæus, stat et Roma; quando cadet colisæus, cadet et Roma; quando cadet Roma, cadet et mundus ("as long as the Colossus stands, so shall Rome; when the Colossus falls, Rome shall fall; when Rome falls, so falls the world").[11] This is often mistranslated to refer to the Colosseum rather than the Colossus (as in, for instance, Byron's poem Childe Harold's Pilgrimage). However, at the time that the Pseudo-Bede wrote, the masculine noun coliseus was applied to the statue rather than to what was still known as the Flavian amphitheatre.

The Colossus did eventually fall, possibly being pulled down to reuse its bronze. By the year 1000 the name "Colosseum" had been coined to refer to the amphitheatre. The statue itself was largely forgotten and only its base survives, situated between the Colosseum and the nearby Temple of Venus and Roma.[12]

The name further evolved to Coliseum during the Middle Ages. In Italy, the amphitheatre is still known as il Colosseo, and other Romance languages have come to use similar forms such as le Colisée (French), el Coliseo (Spanish) and o Coliseu (Portuguese).

Construction of the Colosseum began under the rule of the Emperor Vespasian[3] in around 70–72AD. The site chosen was a flat area on the floor of a low valley between the Caelian, Esquiline and Palatine Hills, through which a canalised stream ran. By the 2nd century BC the area was densely inhabited. It was devastated by the Great Fire of Rome in AD 64, following which Nero seized much of the area to add to his personal domain. He built the grandiose Domus Aurea on the site, in front of which he created an artificial lake surrounded by pavilions, gardens and porticoes. The existing Aqua Claudia aqueduct was extended to supply water to the area and the gigantic bronze Colossus of Nero was set up nearby at the entrance to the Domus Aurea.[12]

Although the Colossus was preserved, much of the Domus Aurea was torn down. The lake was filled in and the land reused as the location for the new Flavian Amphitheatre. Gladiatorial schools and other support buildings were constructed nearby within the former grounds of the Domus Aurea. According to a reconstructed inscription found on the site, "the emperor Vespasian ordered this new amphitheatre to be erected from his general's share of the booty." This is thought to refer to the vast quantity of treasure seized by the Romans following their victory in the Great Jewish Revolt in 70AD. The Colosseum can be thus interpreted as a great triumphal monument built in the Roman tradition of celebrating great victories[12], placating the Roman people instead of returning soldiers. Vespasian's decision to build the Colosseum on the site of Nero's lake can also be seen as a populist gesture of returning to the people an area of the city which Nero had appropriated for his own use. In contrast to many other amphitheatres, which were located on the outskirts of a city, the Colosseum was constructed in the city centre; in effect, placing it both literally and symbolically at the heart of Rome.

The Colosseum had been completed up to the third story by the time of Vespasian's death in 79. The top level was finished and the building inaugurated by his son, Titus, in 80.[3] Dio Cassius recounts that over 9,000 wild animals were killed during the inaugural games of the amphitheatre. The building was remodelled further under Vespasian's younger son, the newly designated Emperor Domitian, who constructed the hypogeum, a series of underground tunnels used to house animals and slaves. He also added a gallery to the top of the Colosseum to increase its seating capacity.

In 217, the Colosseum was badly damaged by a major fire (caused by lightning, according to Dio Cassius[13]) which destroyed the wooden upper levels of the amphitheatre's interior. It was not fully repaired until about 240 and underwent further repairs in 250 or 252 and again in 320. An inscription records the restoration of various parts of the Colosseum under Theodosius II and Valentinian III (reigned 425–455), possibly to repair damage caused by a major earthquake in 443; more work followed in 484[14] and 508. The arena continued to be used for contests well into the 6th century, with gladiatorial fights last mentioned around 435. Animal hunts continued until at least 523, when Anicius Maximus celebrated his consulship with some venationes, criticised by King Theodoric the Great for their high cost.

The Colosseum underwent several radical changes of use during the medieval period. By the late 6th century a small church had been built into the structure of the amphitheatre, though this apparently did not confer any particular religious significance on the building as a whole. The arena was converted into a cemetery. The numerous vaulted spaces in the arcades under the seating were converted into housing and workshops, and are recorded as still being rented out as late as the 12th century. Around 1200 the Frangipani family took over the Colosseum and fortified it, apparently using it as a castle.

Severe damage was inflicted on the Colosseum by the great earthquake in 1349, causing the outer south side, lying on a less stable alluvional terrain, to collapse. Much of the tumbled stone was reused to build palaces, churches, hospitals and other buildings elsewhere in Rome. A religious order moved into the northern third of the Colosseum in the mid-14th century and continued to inhabit it until as late as the early 19th century. The interior of the amphitheatre was extensively stripped of stone, which was reused elsewhere, or (in the case of the marble façade) was burned to make quicklime.[12] The bronze clamps which held the stonework together were pried or hacked out of the walls, leaving numerous pockmarks which still scar the building today.

During the 16th and 17th century, Church officials sought a productive role for the vast derelict hulk of the Colosseum. Pope Sixtus V (1585–1590) planned to turn the building into a wool factory to provide employment for Rome's prostitutes, though this proposal fell through with his premature death.[15] In 1671 Cardinal Altieri authorized its use for bullfights; a public outcry caused the idea to be hastily abandoned.

In 1749, Pope Benedict XIV endorsed as official Church policy the view that the Colosseum was a sacred site where early Christians had been martyred. He forbade the use of the Colosseum as a quarry and consecrated the building to the Passion of Christ and installed Stations of the Cross, declaring it sanctified by the blood of the Christian martyrs who perished there (see Christians and the Colosseum). However there is no historical evidence to support Benedict's claim, nor is there even any evidence that anyone prior to the 16th century suggested this might be the case; the Catholic Encyclopedia concludes that there are no historical grounds for the supposition. Later popes initiated various stabilization and restoration projects, removing the extensive vegetation which had overgrown the structure and threatened to damage it further. The façade was reinforced with triangular brick wedges in 1807 and 1827, and the interior was repaired in 1831, 1846 and in the 1930s. The arena substructure was partly excavated in 1810–1814 and 1874 and was fully exposed under Benito Mussolini in the 1930s.

The Colosseum is today one of Rome's most popular tourist attractions, receiving millions of visitors annually. The effects of pollution and general deterioration over time prompted a major restoration programme carried out between 1993 and 2000, at a cost of 40 billion Italian lire ($19.3m / €20.6m at 2000 prices). In recent years it has become a symbol of the international campaign against capital punishment, which was abolished in Italy in 1948. Several anti–death penalty demonstrations took place in front of the Colosseum in 2000. Since that time, as a gesture against the death penalty, the local authorities of Rome change the color of the Colosseum's night time illumination from white to gold whenever a person condemned to the death penalty anywhere in the world gets their sentence commuted or is released,[16] or if a jurisdiction abolishes the death penalty. Most recently, the Colosseum was illuminated in gold when capital punishment was abolished in the American state of New Mexico in April 2009.

Because of the ruined state of the interior, it is impractical to use the Colosseum to host large events; only a few hundred spectators can be accommodated in temporary seating. However, much larger concerts have been held just outside, using the Colosseum as a backdrop. Performers who have played at the Colosseum in recent years have included Ray Charles (May 2002),[18] Paul McCartney (May 2003),[19] Elton John (September 2005),[20] and Billy Joel (July 2006).

Exterior

Unlike earlier Greek theatres that were built into hillsides, the Colosseum is an entirely free-standing structure. It derives its basic exterior and interior architecture from that of two Roman theatres back to back. It is elliptical in plan and is 189 meters (615 ft / 640 Roman feet) long, and 156 meters (510 ft / 528 Roman feet) wide, with a base area of 6 acres (24,000 m2). The height of the outer wall is 48 meters (157 ft / 165 Roman feet). The perimeter originally measured 545 meters (1,788 ft / 1,835 Roman feet). The central arena is an oval 87 m (287 ft) long and 55 m (180 ft) wide, surrounded by a wall 5 m (15 ft) high, above which rose tiers of seating.

The outer wall is estimated to have required over 100,000 cubic meters (131,000 cu yd) of travertine stone which were set without mortar held together by 300 tons of iron clamps.[12] However, it has suffered extensive damage over the centuries, with large segments having collapsed following earthquakes. The north side of the perimeter wall is still standing; the distinctive triangular brick wedges at each end are modern additions, having been constructed in the early 19th century to shore up the wall. The remainder of the present-day exterior of the Colosseum is in fact the original interior wall.

The surviving part of the outer wall's monumental façade comprises three stories of superimposed arcades surmounted by a podium on which stands a tall attic, both of which are pierced by windows interspersed at regular intervals. The arcades are framed by half-columns of the Tuscan, Ionic, and Corinthian orders, while the attic is decorated with Corinthian pilasters.[21] Each of the arches in the second- and third-floor arcades framed statues, probably honoring divinities and other figures from Classical mythology.

Two hundred and forty mast corbels were positioned around the top of the attic. They originally supported a retractable awning, known as the velarium, that kept the sun and rain off spectators. This consisted of a canvas-covered, net-like structure made of ropes, with a hole in the center.[3] It covered two-thirds of the arena, and sloped down towards the center to catch the wind and provide a breeze for the audience. Sailors, specially enlisted from the Roman naval headquarters at Misenum and housed in the nearby Castra Misenatium, were used to work the velarium.[22]

The Colosseum's huge crowd capacity made it essential that the venue could be filled or evacuated quickly. Its architects adopted solutions very similar to those used in modern stadiums to deal with the same problem. The amphitheatre was ringed by eighty entrances at ground level, 76 of which were used by ordinary spectators.[3] Each entrance and exit was numbered, as was each staircase. The northern main entrance was reserved for the Roman Emperor and his aides, whilst the other three axial entrances were most likely used by the elite. All four axial entrances were richly decorated with painted stucco reliefs, of which fragments survive. Many of the original outer entrances have disappeared with the collapse of the perimeter wall, but entrances XXIII (23) to LIV (54) still survive.[12]

Spectators were given tickets in the form of numbered pottery shards, which directed them to the appropriate section and row. They accessed their seats via vomitoria (singular vomitorium), passageways that opened into a tier of seats from below or behind. These quickly dispersed people into their seats and, upon conclusion of the event or in an emergency evacuation, could permit their exit within only a few minutes. The name vomitoria derived from the Latin word for a rapid discharge, from which English derives the word vomit.

Interior

According to the Codex-Calendar of 354, the Colosseum could accommodate 87,000 people, although modern estimates put the figure at around 50,000. They were seated in a tiered arrangement that reflected the rigidly stratified nature of Roman society. Special boxes were provided at the north and south ends respectively for the Emperor and the Vestal Virgins, providing the best views of the arena. Flanking them at the same level was a broad platform or podium for the senatorial class, who were allowed to bring their own chairs. The names of some 5th century senators can still be seen carved into the stonework, presumably reserving areas for their use.

The tier above the senators, known as the maenianum primum, was occupied by the non-senatorial noble class or knights (equites). The next level up, the maenianum secundum, was originally reserved for ordinary Roman citizens (plebians) and was divided into two sections. The lower part (the immum) was for wealthy citizens, while the upper part (the summum) was for poor citizens. Specific sectors were provided for other social groups: for instance, boys with their tutors, soldiers on leave, foreign dignitaries, scribes, heralds, priests and so on. Stone (and later marble) seating was provided for the citizens and nobles, who presumably would have brought their own cushions with them. Inscriptions identified the areas reserved for specific groups.

Another level, the maenianum secundum in legneis, was added at the very top of the building during the reign of Domitian. This comprised a gallery for the common poor, slaves and women. It would have been either standing room only, or would have had very steep wooden benches. Some groups were banned altogether from the Colosseum, notably gravediggers, actors and former gladiators.

Each tier was divided into sections (maeniana) by curved passages and low walls (praecinctiones or baltei), and were subdivided into cunei, or wedges, by the steps and aisles from the vomitoria. Each row (gradus) of seats was numbered, permitting each individual seat to be exactly designated by its gradus, cuneus, and number.

The arena itself was 83 meters by 48 meters (272 ft by 157 ft / 280 by 163 Roman feet).[12] It comprised a wooden floor covered by sand (the Latin word for sand is harena or arena), covering an elaborate underground structure called the hypogeum (literally meaning "underground"). Little now remains of the original arena floor, but the hypogeum is still clearly visible. It consisted of a two-level subterranean network of tunnels and cages beneath the arena where gladiators and animals were held before contests began. Eighty vertical shafts provided instant access to the arena for caged animals and scenery pieces concealed underneath; larger hinged platforms, called hegmata, provided access for elephants and the like. It was restructured on numerous occasions; at least twelve different phases of construction can be seen.[12]

The hypogeum was connected by underground tunnels to a number of points outside the Colosseum. Animals and performers were brought through the tunnel from nearby stables, with the gladiators' barracks at the Ludus Magnus to the east also being connected by tunnels. Separate tunnels were provided for the Emperor and the Vestal Virgins to permit them to enter and exit the Colosseum without needing to pass through the crowds.[12]

Substantial quantities of machinery also existed in the hypogeum. Elevators and pulleys raised and lowered scenery and props, as well as lifting caged animals to the surface for release. There is evidence for the existence of major hydraulic mechanisms[12] and according to ancient accounts, it was possible to flood the arena rapidly, presumably via a connection to a nearby aqueduct.

The Colosseum and its activities supported a substantial industry in the area. In addition to the amphitheatre itself, many other buildings nearby were linked to the games. Immediately to the east is the remains of the Ludus Magnus, a training school for gladiators. This was connected to the Colosseum by an underground passage, to allow easy access for the gladiators. The Ludus Magnus had its own miniature training arena, which was itself a popular attraction for Roman spectators. Other training schools were in the same area, including the Ludus Matutinus (Morning School), where fighters of animals were trained, plus the Dacian and Gallic Schools.

Also nearby were the Armamentarium, comprising an armory to store weapons; the Summum Choragium, where machinery was stored; the Sanitarium, which had facilities to treat wounded gladiators; and the Spoliarium, where bodies of dead gladiators were stripped of their armor and disposed of.

Around the perimeter of the Colosseum, at a distance of 18 m (59 ft) from the perimeter, was a series of tall stone posts, with five remaining on the eastern side. Various explanations have been advanced for their presence; they may have been a religious boundary, or an outer boundary for ticket checks, or an anchor for the velarium or awning.

Right next to the Colosseum is also the Arch of Constantine.

he Colosseum was used to host gladiatorial shows as well as a variety of other events. The shows, called munera, were always given by private individuals rather than the state. They had a strong religious element but were also demonstrations of power and family prestige, and were immensely popular with the population. Another popular type of show was the animal hunt, or venatio. This utilized a great variety of wild beasts, mainly imported from Africa and the Middle East, and included creatures such as rhinoceros, hippopotamuses, elephants, giraffes, aurochs, wisents, barbary lions, panthers, leopards, bears, caspian tigers, crocodiles and ostriches. Battles and hunts were often staged amid elaborate sets with movable trees and buildings. Such events were occasionally on a huge scale; Trajan is said to have celebrated his victories in Dacia in 107 with contests involving 11,000 animals and 10,000 gladiators over the course of 123 days.

During the early days of the Colosseum, ancient writers recorded that the building was used for naumachiae (more properly known as navalia proelia) or simulated sea battles. Accounts of the inaugural games held by Titus in AD 80 describe it being filled with water for a display of specially trained swimming horses and bulls. There is also an account of a re-enactment of a famous sea battle between the Corcyrean (Corfiot) Greeks and the Corinthians. This has been the subject of some debate among historians; although providing the water would not have been a problem, it is unclear how the arena could have been waterproofed, nor would there have been enough space in the arena for the warships to move around. It has been suggested that the reports either have the location wrong, or that the Colosseum originally featured a wide floodable channel down its central axis (which would later have been replaced by the hypogeum).[12]

Sylvae or recreations of natural scenes were also held in the arena. Painters, technicians and architects would construct a simulation of a forest with real trees and bushes planted in the arena's floor. Animals would be introduced to populate the scene for the delight of the crowd. Such scenes might be used simply to display a natural environment for the urban population, or could otherwise be used as the backdrop for hunts or dramas depicting episodes from mythology. They were also occasionally used for executions in which the hero of the story — played by a condemned person — was killed in one of various gruesome but mythologically authentic ways, such as being mauled by beasts or burned to death.

The Colosseum today is now a major tourist attraction in Rome with thousands of tourists each year paying to view the interior arena, though entrance for EU citizens is partially subsidised, and under-18 and over-65 EU citizens' entrances are free.[24] There is now a museum dedicated to Eros located in the upper floor of the outer wall of the building. Part of the arena floor has been re-floored. Beneath the Colosseum, a network of subterranean passageways once used to transport wild animals and gladiators to the arena opened to the public in summer 2010.[25]

The Colosseum is also the site of Roman Catholic ceremonies in the 20th and 21st centuries. For instance, Pope Benedict XVI leads the Stations of the Cross called the Scriptural Way of the Cross (which calls for more meditation) at the Colosseum[26][27] on Good Fridays.

In the Middle Ages, the Colosseum was clearly not regarded as a sacred site. Its use as a fortress and then a quarry demonstrates how little spiritual importance was attached to it, at a time when sites associated with martyrs were highly venerated. It was not included in the itineraries compiled for the use of pilgrims nor in works such as the 12th century Mirabilia Urbis Romae ("Marvels of the City of Rome"), which claims the Circus Flaminius — but not the Colosseum — as the site of martyrdoms. Part of the structure was inhabited by a Christian order, but apparently not for any particular religious reason.

It appears to have been only in the 16th and 17th centuries that the Colosseum came to be regarded as a Christian site. Pope Pius V (1566–1572) is said to have recommended that pilgrims gather sand from the arena of the Colosseum to serve as a relic, on the grounds that it was impregnated with the blood of martyrs. This seems to have been a minority view until it was popularised nearly a century later by Fioravante Martinelli, who listed the Colosseum at the head of a list of places sacred to the martyrs in his 1653 book Roma ex ethnica sacra.

Martinelli's book evidently had an effect on public opinion; in response to Cardinal Altieri's proposal some years later to turn the Colosseum into a bullring, Carlo Tomassi published a pamphlet in protest against what he regarded as an act of desecration. The ensuing controversy persuaded Pope Clement X to close the Colosseum's external arcades and declare it a sanctuary, though quarrying continued for some time.

At the instance of St. Leonard of Port Maurice, Pope Benedict XIV (1740–1758) forbade the quarrying of the Colosseum and erected Stations of the Cross around the arena, which remained until February 1874. St. Benedict Joseph Labre spent the later years of his life within the walls of the Colosseum, living on alms, prior to his death in 1783. Several 19th century popes funded repair and restoration work on the Colosseum, and it still retains a Christian connection today. Crosses stand in several points around the arena and every Good Friday the Pope leads a Via Crucis procession to the amphitheatre.

 

Coliseu (Colosseo)

A seguir, um texto, em português, da Wikipédia, a enciclopédia livre:

 

O Coliseu, também conhecido como Anfiteatro Flaviano, deve seu nome à expressão latina Colosseum (ou Coliseus, no latim tardio), devido à estátua colossal de Nero, que ficava perto a edificação. Localizado no centro de Roma, é uma excepção de entre os anfiteatros pelo seu volume e relevo arquitectónico. Originalmente capaz de albergar perto de 50 000 pessoas, e com 48 metros de altura, era usado para variados espetáculos. Foi construído a leste do fórum romano e demorou entre 8 a 10 anos a ser construído.

O Coliseu foi utilizado durante aproximadamente 500 anos, tendo sido o último registro efetuado no século VI da nossa era, bastante depois da queda de Roma em 476. O edifício deixou de ser usado para entretenimento no começo da era medieval, mas foi mais tarde usado como habitação, oficina, forte, pedreira, sede de ordens religiosas e templo cristão.

Embora esteja agora em ruínas devido a terremotos e pilhagens, o Coliseu sempre foi visto como símbolo do Império Romano, sendo um dos melhores exemplos da sua arquitectura. Actualmente é uma das maiores atrações turísticas em Roma e em 7 de julho de 2007 foi eleita umas das "Sete maravilhas do mundo moderno". Além disso, o Coliseu ainda tem ligações à igreja, com o Papa a liderar a procissão da Via Sacra até ao Coliseu todas as Sextas-feiras Santas.

O coliseu era um local onde seriam exibidos toda uma série de espectáculos, inseridos nos vários tipos de jogos realizados na urbe. Os combates entre gladiadores, chamados muneras, eram sempre pagos por pessoas individuais em busca de prestígio e poder em vez do estado. A arena (87,5 m por 55 m) possuía um piso de madeira, normalmente coberto de areia para absorver o sangue dos combates (certa vez foi colocada água na representação de uma batalha naval), sob o qual existia um nível subterrâneo com celas e jaulas que tinham acessos diretos para a arena; Alguns detalhes dessa construção, como a cobertura removível que poupava os espectadores do sol, são bastante interessantes, e mostram o refinamento atingido pelos construtores romanos. Formado por cinco anéis concêntricos de arcos e abóbadas, o Coliseu representa bem o avanço introduzido pelos romanos à engenharia de estruturas. Esses arcos são de concreto (de cimento natural) revestidos por alvenaria. Na verdade, a alvenaria era construída simultaneamente e já servia de forma para a concretagem. Outro tipo de espetáculos era a caça de animais, ou venatio, onde eram utilizados animais selvagens importados de África. Os animais mais utilizados eram os grandes felinos como leões, leopardos e panteras, mas animais como rinocerontes, hipopótamos, elefantes, girafas, crocodilos e avestruzes eram também utilizados. As caçadas, tal como as representações de batalhas famosas, eram efetuadas em elaborados cenários onde constavam árvores e edifícios amovíveis.

Estas últimas eram por vezes representadas numa escala gigante; Trajano celebrou a sua vitória em Dácia no ano 107 com concursos envolvendo 11 000 animais e 10 000 gladiadores no decorrer de 123 dias.

Segundo o documentário produzido pelo canal televisivo fechado, History Channel, o Coliseu também era utilizado para a realização de naumaquias, ou batalhas navais. O coliseu era inundado por dutos subterrâneos alimentados pelos aquedutos que traziam água de longe. Passada esta fase, foi construída uma estrutura, que é a que podemos ver hoje nas ruínas do Coliseu, com altura de um prédio de dois andares, onde no passado se concentravam os gladiadores, feras e todo o pessoal que organizava os duelos que ocorreriam na arena. A arena era como um grande palco, feito de madeira, e se chama arena, que em italiano significa areia, porque era jogada areia sob a estrutura de madeira para esconder as imperfeições. Os animais podiam ser inseridos nos duelos a qualquer momento por um esquema de elevadores que surgiam em alguns pontos da arena; o filme "Gladiador" retrata muito bem esta questão dos elevadores. Os estudiosos, há pouco tempo, descobriram uma rede de dutos inundados por baixo da arena do Coliseu. Acredita-se que o Coliseu foi construído onde, outrora, foi o lago do Palácio Dourado de Nero; O imperador Vespasiano escolheu o local da construção para que o mal causado por Nero fosse esquecido por uma construção gloriosa.

Sylvae, ou recreações de cenas naturais eram também realizadas no Coliseu. Pintores, técnicos e arquitectos construiriam simulações de florestas com árvores e arbustos reais plantados no chão da arena. Animais seriam então introduzidos para dar vida à simulação. Esses cenários podiam servir só para agrado do público ou como pano de fundo para caçadas ou dramas representando episódios da mitologia romana, tão autênticos quanto possível, ao ponto de pessoas condenadas fazerem o papel de heróis onde eram mortos de maneiras horríveis mas mitologicamente autênticas, como mutilados por animais ou queimados vivos.

Embora o Coliseu tenha funcionado até ao século VI da nossa Era, foram proibidos os jogos com mortes humanas desde 404, sendo apenas massacrados animais como elefantes, panteras ou leões.

O Coliseu era sobretudo um enorme instrumento de propaganda e difusão da filosofia de toda uma civilização, e tal como era já profetizado pelo monge e historiador inglês Beda na sua obra do século VII "De temporibus liber": "Enquanto o Coliseu se mantiver de pé, Roma permanecerá; quando o Coliseu ruir, Roma ruirá e quando Roma cair, o mundo cairá".

A construção do Coliseu foi iniciada por Vespasiano, nos anos 70 da nossa era. O edifício foi inaugurado por Tito, em 80, embora apenas tivesse sido finalizado poucos anos depois. Empresa colossal, este edifício, inicialmente, poderia sustentar no seu interior cerca de 50 000 espectadores, constando de três andares. Aquando do reinado de Alexandre Severo e Gordiano III, é ampliado com um quarto andar, podendo suster agora cerca de 90 000 espectadores. A grandiosidade deste monumento testemunha verdadeiramente o poder e esplendor de Roma na época dos Flávios.

Os jogos inaugurais do Coliseu tiveram lugar ano 80, sob o mandato de Tito, para celebrar a finalização da construção. Depois do curto reinado de Tito começar com vários meses de desastres, incluindo a erupção do Monte Vesúvio, um incêndio em Roma, e um surto de peste, o mesmo imperador inaugurou o edifício com uns jogos pródigos que duraram mais de cem dias, talvez para tentar apaziguar o público romano e os deuses. Nesses jogos de cem dias terão ocorrido combates de gladiadores, venationes (lutas de animais), execuções, batalhas navais, caçadas e outros divertimentos numa escala sem precedentes.

O Coliseu, como não se encontrava inserido numa zona de encosta, enterrado, tal como normalmente sucede com a generalidade dos teatros e anfiteatros romanos, possuía um “anel” artificial de rocha à sua volta, para garantir sustentação e, ao mesmo tempo, esta substrutura serve como ornamento ao edifício e como condicionador da entrada dos espectadores. Tal como foi referido anteriormente, possuía três pisos, sendo mais tarde adicionado um outro. É construído em mármore, pedra travertina, ladrilho e tufo (pedra calcária com grandes poros). A sua planta elíptica mede dois eixos que se estendem aproximadamente de 190 m por 155 m. A fachada compõe-se de arcadas decoradas com colunas dóricas, jónicas e coríntias, de acordo com o pavimento em que se encontravam. Esta subdivisão deve-se ao facto de ser uma construção essencialmente vertical, criando assim uma diversificação do espaço.

 

Os assentos eram em mármore e a cavea, escadaria ou arquibancada, dividia-se em três partes, correspondentes às diferentes classes sociais: o podium, para as classes altas; as maeniana, sector destinado à classe média; e os portici, ou pórticos, construídos em madeira, para a plebe e as mulheres. O pulvinar, a tribuna imperial, encontrava-se situada no podium e era balizada pelos assentos reservados aos senadores e magistrados. Rampas no interior do edifício facilitavam o acesso às várias zonas de onde podiam visualizar o espectáculo, sendo protegidos por uma barreira e por uma série de arqueiros posicionados numa passagem de madeira, para o caso de algum acidente. Por cima dos muros ainda são visíveis as mísulas, que sustentavam o velarium, enorme cobertura de lona destinada a proteger do sol os espectadores e, nos subterrâneos, ficavam as jaulas dos animais, bem como todas as celas e galerias necessárias aos serviços do anfiteatro.

O monumento permaneceu como sede principal dos espetáculos da urbe romana até ao período do imperador Honorius, no século V. Danificado por um terremoto no começo do mesmo século, foi alvo de uma extensiva restauração na época de Valentinianus III. Em meados do século XIII, a família Frangipani transformou-o em fortaleza e, ao longo dos séculos XV e XVI, foi por diversas vezes saqueado, perdendo grande parte dos materiais nobres com os quais tinha sido construído.

Os relatos romanos referem-se a cristãos sendo martirizados em locais de Roma descritos pouco pormenorizadamente (no anfiteatro, na arena...), quando Roma tinha numerosos anfiteatros e arenas. Apesar de muito provavelmente o Coliseu não ter sido utilizado para martírios, o Papa Bento XIV consagrou-o no século XVII à Paixão de Cristo e declarou-o lugar sagrado. Os trabalhos de consolidação e restauração parcial do monumento, já há muito em ruínas, foram feitos sobretudo pelos pontífices Gregório XVI e Pio IX, no século XIX.

Capable of carrying 60 car and even full sized coaches the vehicle deck on The Princess Anne was cavernous. At the moment it is being used to house a number of smaller exhibits and at least three wheelie bins.

Israeli Police Yamam unit during Counter Terror Training

 

The Yamam (Hebrew: ימ"מ‎, an acronym for Special Central Unit (יחידה מרכזית מיוחדת, Yehida Merkazit Meyuhedet)) is the elite civilian counter-terrorism unit in Israel. The Yamam is capable of both hostage-rescue operations and offensive take-over raids against targets in civilian areas. Besides military duties, it also performs SWAT duties and undercover police work.

 

Name and structure

 

In Israel the Yamam is also known as the "Unit for Counter-Terror Warfare" (Hebrew: היחידה ללוחמה בטרור‎). It is subordinate to the Ministry of Internal Security central command and is part of the civilian Israel Police force, specifically the Israel Border Police. Its operators and officers are professional policemen on payroll, usually with infantry experience from their military service within the Israel Defense Forces. Yamam recruits its members exclusively from Israeli units.

 

Responsibilities

 

The unit is primarily responsible for civilian hostage rescue within Israel's borders, but from about the mid-1990s it has also been used for tasks such as arresting police suspects who have barricaded themselves in structures and requiring specialized extraction methods, as well as in personal security for VIPs and in counter-terror operations within the West Bank and Gaza Strip. The Yamam are schooled in basic Arabic and dress to assimilate within the Arab population to avoid detection in order to carry out raids to arrest those suspected of conducting terrorist activities within Israel.

However, most of the Yamam's activity is classified, and published Yamam operations are often credited to other units.

 

Organisation

 

The Yamam has around 200 officers, and consists a headquarters element, an intelligence section and a small team responsible for the development of new operational techniques and testing new equipment. Aside from these central elements, the bulk of the unit is divided into a number of sections, each consisting of five teams, each containing operators with a particular specialization, so that the section includes within its numbers all the elements needed for a successful operation: roping team, entry team, medic team, sniping team, dog team, EOD team (demolition and bomb disposal). Thus, whereas an IDF special forces operation needs to assemble elements from different specialist units, in Yamam, they are all permanently part of the same unit, living, training and operating together.

 

Officers

 

Applicants for Yamam must be between 22 and 30 years old and must have completed their three-year infantry service in the IDF with a level 7 of IDF training or higher, although no previous police experience is required. Unlike American SWAT teams, the YAMAM is a professional unit with only combat duties and no other police type work. The selection process includes a "hell week" said to be one of the hardest in the world. This level of difficulty is achieved because all the applicants are already seasoned combat soldiers, like the US Delta force. The skills they are looking for in every candidate are: intelligence, physical fitness, motivation, trustworthiness, accountability, maturity, stability, judgment, decisiveness, teamwork, influence, and communication. Training lasts 6 months and is carried out in the unit's own training center, although some use is made of the facilities at the IDF Counter Terror Warfare School (LOTAR, Unit 707.) The course is divided into an three-month general CT training period at the end of which recruits are selected for their specialization and then concentrate for the remaining four months on that specialization. Upon graduation, individuals are posted to fill gaps in the sections. Yamam considers that it has several advantages over the IDF counter-terror units, first, because the men are more mature, most in their mid 30's and early 40's, and spend much longer in the unit than the equivalent military units, and, second, because the units contain a far broader range of ages and experience.

The Yamam is self-dependent, training its own operators in all fields, such as sniping, reconnaissance, dog operating, bomb disposal, etc. As a result, the Yamam has a rapid deployment time and high coordination between various squads (sniping squad, entry team, engagement force, etc.).

 

+++ DISCLAIMER +++

Nothing you see here is real, even though the model, the conversion or the presented background story might be based on historical facts. BEWARE!

  

Some background:

After the country's independence from the United Kingdom, after its departure from the European Union in 2017, the young Republic of Scotland Air Corps (locally known as Poblachd na h-Alba Adhair an Airm) started a major procurement program to take over most basic duties the Royal Air Force formerly had taken over in Northern Britain. This procurement was preceded by a White Paper published by the Scottish National Party (SNP) in 2013, which had stated that an independent Scotland would have an air force equipped with up to 16 air defense aircraft, six tactical transports, utility rotorcraft and maritime patrol aircraft, and be capable of “contributing excellent conventional capabilities” to NATO. According to the document, “Key elements of air forces in place at independence, equipped initially from a negotiated share of current UK assets, will secure core tasks, principally the ability to police Scotland’s airspace, within NATO.” An in-country air command and control capability would be established within five years of a decision in favor of independence, it continues, with staff also to be “embedded within NATO structures”.

 

Outlining its ambition to establish an air force with an eventual 2,000 uniformed personnel and 300 reservists, the SNP stated the organization would initially be equipped with “a minimum of 12 interceptors in the Eurofighter/Typhoon class, based at Lossiemouth, a tactical air transport squadron, including around six Lockheed Martin C-130J Hercules, and a helicopter squadron”. The latter would not only have to take over transport duties for the army, there was also a dire need to quickly replace the former Royal Air Force’s Search and Rescue (SAR) capabilities and duties in the North with domestic resources, after this role was handed over to civilian contractor Bristow Helicopters and the RAF’s SAR units had been disbanded.

 

This led to the procurement of six AS365 Dauphin helicopters as an initial measure to keep up basic SAR capabilities, with the prospects of procuring more to become independent from the Bristow Helicopters contract. These aircraft were similar to the Eurocopter SA 366 MH-65 “Dolphin” for the United States Coast Guard but differed in many ways from them and also from any other navalized SA365 variant.

For the RoScAC’s SAR squadron, the SA 365 was taken as a starting point, but the helicopter was heavily modified and locally re-christened “Leumadair” (= Dolphin).

 

The most obvious new feature of the unique Scottish rescue variant was a fixed landing gear with the main wheels on short “stub wings” for a wider stance, stabilizing the helicopter during shipboard landings and in case of an emergency water landing - the helicopter was not able to perform water landings, even though inflatable emergency landing floats were typically fitted. Another obvious difference to other military Dauphin versions was the thimble radome on the nose for an RDR-1600 search and weather radar which is capable of detecting small targets at sea as far as 25 nautical miles away. This layout was chosen to provide the pilots with a better field of view directrly ahead of the helicopter. Additionally, an electro-optical sensor turret with an integrated FLIR sensor was mounted in a fully rotatable turret under the nose, giving the helicopter full all-weather capabilities. Less obvious were a digital glass cockpit and a computerized flight management system, which integrated state-of-the-art communications and navigation equipment. This system provided automatic flight control, and at the pilot's direction, the system would bring the aircraft to a stable hover 50 feet (15 m) above a selected object, an important safety feature in darkness or inclement weather. Selected search patterns could be flown automatically, freeing the pilot and copilot to concentrate on sighting & searching the object.

To improve performance and safety margin, more powerful Turbomeca Arriel 2C2-CG engines were used. Seventy-five percent of the structure—including rotor head, rotor blades and fuselage—consisted of corrosion-resistant composite materials. The rotor blades themselves were new, too, with BERP “paddles”at their tips, a new aerofoil and increased blade twist for increased lifting-capability and maximum speed, to compensate for the fixed landing gear and other external equipment that increased drag. To prevent leading edge erosion the blade used a rubber-based tape rather than the polyurethane used on earlier helicopters.

 

The “Leumadair HR.1”, so its official designation, became operational in mid-2019. Despite being owned by the government, the helicopters received civil registrations (SC-LEA - -LEF) and were dispersed along the Scottish coastline. They normally carried a crew of four: Pilot, Copilot, Flight Mechanic and Rescue Swimmer, even though regular flight patrols were only excuted with a crew of three. The Leumadair HR.1 was used by the RoScAC primarily for search and rescue missions, but also for homeland security patrols, cargo, drug interdiction, ice breaking, and pollution control. While the helicopters operated unarmed, they could be outfitted with manually operated light or medium machine guns in their doors.

However, the small fleet of only six helicopters was far from being enough to cover the Scottish coast and the many islands up north, so that the government prolonged the contract with Bristow Helicopters in late 2019 for two more years, and the procurement of further Leumadair HR.1 helicopters was decided in early 2020. Twelve more helicopters were ordered en suite and were expected to arrive in late 2021.

  

General characteristics:

Crew: 2 pilots and 2 crew

Length: 12,06 m (39 ft 2 1/2 in)

Height: 4 m (13 ft 1 in)

Main rotor diameter: 12,10 m (39 ft 7 1/2 in)

Main rotor area: 38.54 m² (414.8 sq ft)

Empty weight: 3,128 kg (6,896 lb)

Max takeoff weight: 4,300 kg (9,480 lb)

 

Powerplant:

2× Turbomeca Arriel 2C2-CG turboshaft engines, 636 kW (853 hp) each

 

Performance:

Maximum speed: 330 km/h (210 mph, 180 kn)

Cruise speed: 240 km/h (150 mph, 130 kn)

Range: 658 km (409 mi, 355 nmi)

Service ceiling: 5,486 m (17,999 ft)

 

Armament:

None installed, but provisions for a 7.62 mm M240 machine gun or a Barrett M107 0.50 in (12.7

mm) caliber precision rifle in each side door

  

The kit and its assembly:

Another chapter in my fictional alternative reality in which Scotland became an independent Republic and separated from the UK in 2017. Beyond basic aircraft for the RoScAC’s aerial defense duties I felt that maritime rescue would be another vital task for the nascent air force – and the situation that Great Britain had outsourced the SAR job to a private company called for a new solution for the independent Scotland. This led to the consideration of a relatively cheap maritime helicopter, and my choice fell on the SA365 ‘Daupin’, which has been adapted to such duties in various variants.

 

As a starting point there’s the Matchbox SA365 kit from 1983, which is a typical offer from the company: a solid kit, with mixed weak spots and nice details (e. g. the cockpit with a decent dashboard and steering columns/pedals for the crew). Revell has re-boxed this kit in 2002 as an USCG HH-65A ‘Dolphin’, but it’s technically only a painting option and the kit lacks any optional parts to actually build this type of helicopter in an authentic fashion - there are some subtle differences, and creating a convincing HH-65 from it would take a LOT of effort. Actually, it's a real scam from Revell to market the Matchbox Dauphin as a HH-65!

 

However, it was my starting basis, and for a modernized/navalized/military version of the SA365 I made some changes. For instance, I gave the helicopter a fixed landing gear, with main wheels stub wings taken from a Pavla resin upgrade/conversion set for a Lynx HAS.2, which also comes with better wheels than the Matchbox kit. The Dauphin’s landing gear wells were filled with 2C putty and in the same process took the stub wings. The front landing gear well was filled with putty, too, and a adapter to hold the front twin wheel strut was embedded. Lots of lead were hidden under the cockpit floor to ensure that this model would not becaome a tail sitter.

A thimble radome was integrated into the nose with some PSR – I opted for this layout because the fixed landing gear would block 360° radar coverage under the fuselage, and there’s not too much ground clearance or space above then cabin for a radome. Putting it on top of the rotor would have been the only other option, but I found this rather awkward. As a side benefit, the new nose changes the helicopter’s silhouette well and adds to a purposeful look.

 

The rotor blades were replaced with resin BERP blades, taken from another Pavla Lynx conversion set (for the Hobby Boss kit). Because their attachment points were very different from the Matchbox Dauphin rotor’s construction, I had to improvise a little. A rather subtle change, but the result looks very plausible and works well. Other external extras are two inflatable floating devices along the lower fuselage from a Mistercraft ASW AB 212 (UH-1) kit, the winch at port side was scratched with a piece from the aforementioned BK 117 and styrene bits. Some blade antennae were added and a sensor turret was scratched and placed in front of the front wheels. Additional air scoops for the gearbox were added, too. Inside, I added two (Matchbox) pilot figures to the cockpit, plus a third seat for a medic/observer, a storage/equipment box and a stretcher from a Revell BK 117 rescue helicopter kit. This kit also donated some small details like the rear-view mirror for the pilot and the wire-cutters - not a typical detail for a helicopter operating over the open sea, but you never know...

 

The only other adition is a technical one: I integrated a vertical styrene pipe behind the cabin as a display holder adapter for the traditional hoto shooting's in-flight scenes.

  

Painting and markings:

It took some time to settle upon a design. I wanted something bright – initially I thought about Scottish colors (white and blue), but that was not garish enough, even with some dayglo additions. The typical all-yellow RAF SAR livery was also ruled out. In the end I decided to apply a more or less uniform livery in a very bright red: Humbrol 238, which is, probably due to trademark issues, marketed as “Arrow Red (= Red Arrows)” and effectively an almost fluorescent pinkish orange-red! Only the black anti-glare panel in front of the windscreen, the radome and the white interior of the fenestron tail rotor were painted, too, the rest was created with white decal stripes and evolved gradually. Things started with a white 2mm cheatline, then came the horizontal stripes on the tail, and taking this "theme" further I added something similar to the flanks as a high contrast base for the national markings. These were improvised, too, with a 6mm blue disc and single 1.5 mm bars to create a Scottish flag. The stancils were taken from the OOB decal sheet. The interior became medium grey, the crew received bright orange jumpsuits and white "bone domes".

 

No black ink washing or post-panel-shading was done, since the Dauphin has almost no surface details to emphasize, and I wanted a new and clean look. Besides, with wll the white trim, there was already a lot going on on the hull, so that I kept things "as they were". Finally, the model was sealed with a coat of semi-gloss acrylic varnish for a light shine, except for the rotor blades and the anti-glare panel, which became matt.

  

Quite a tricky project. While the Matchbox Dauphin is not a complex kit you need patience and have to stick to the assembly order to put the hull together. PSR is needed, esp. around the engine section and for the underside. On the other side, despite being a simple model, you get a nice Dauphin from the kit - but NOT a HH-65, sorry. My fictional conversion is certainly not better, but the bright result with its modifications looks good and quite convincing, though.

+++ DISCLAIMER +++

Nothing you see here is real, even though the conversion or the presented background story might be based historical facts. BEWARE!

  

Some background:

The Wasp was a transonic British jet-powered fighter aircraft that was developed by Folland for the Royal Air Force (RAF) during the late 1940s and early 1950s. The Wasp’s origins could be traced back to a privately funded 1952 concept for a bigger and more capable day fighter aircraft than Folland’s very light Midget/Gnat. The Wasp’s development had been continued until the Gnat’s service introduction, and by then it had evolved under the handle “Fo-145” into a supersonic aircraft that took advantage of the new Armstrong Siddeley Sapphire turbojet engine, swept wings and area rule. The aircraft was built with the minimum airframe size to take the reheated Saphire and a radar system that would allow it to deploy the new de Havilland Blue Jay (later Firestreak) guided air-to-air missile. In this form the aircraft was expected to surpass the Royal Air Force’s contemporary day fighter, the only gun-armed Hawker Hunter, which had been in service since 1954, while using basically the same engine as its F.2 variant, in both performance and armament aspects. The missile-armed Wasp was also expected to replace the disappointing Supermarine Swift and the Fairey Fireflash AAMs that had been developed for it.

The Wasp strongly resembled the smaller Gnat, with a similar but much thinner shoulder mounted wing, with a sweep of 35° at quarter chord, but the new aircraft featured some innovations. Beyond the area-ruled fuselage, the aircraft had full-span leading edge slats and trailing edge flaps with roll control achieved using spoilers rather than traditional ailerons. Anticipating supersonic performance, the tailplane was all-moving. The cockpit had been raised and offered the pilot a much better all-round field of view.

 

The Wasp was armed with four 30 mm (1.18 in) ADEN cannon, located under the air intakes. Each gun had a provision of 125 rounds, from form a mutual ventral ammunition bay that could be quickly replaced. Four underwing hardpoints could carry an ordnance load of up to 4.000 lb, and the Wasp’s main armament consisted of up to four IR-guided “Firestreak” AAMs. To effectively deploy them, however, a radar system was necessary. For launch, the missile seeker was slaved to the Wasp’s AI.Mk.20 X-band radar until lock was achieved and the weapon was launched, leaving the interceptor free to acquire another target. The AI.Mk.20 had been developed by EKCO since 1953 under the development label “Green Willow” for the upcoming EE Lightning interceptor, should the latter’s more complex and powerful Ferranti AIRPASS system fail. A major advantage of the AI.Mk.20 was that it had been designed as a single unit so it could be fit into the nose of smaller single-seat fighters, despite its total weight of roughly 400 lb (200 kg). For the Firestreak AAM, EKCO had developed a spiral-scan radar with a compact 18 in (460 mm) antenna that offered an effective range of about 10 miles (16 km), although only against targets very close to the centerline of the radar. The radar’s maximum detection range was 25 mi (40 km) and the system also acted as a ranging radar, providing range input to the gyro gunsight for air-to-air gunnery.

Beyond Firestreaks, the Wasp could also carry drop tanks (which were area-ruled and coulc only be carried on the inner pair of pylons), SNEB Pods with eighteen 68 mm (2.68 in) unguided rocket projectiles against air and ground targets, or iron bombs of up to 1.000 lb caliber. Other equipment included a nose-mounted, and a forward-facing gun camera.

 

The Royal Air Force was sufficiently impressed to order two prototypes. Since the afterburning version of the Sapphire was not ready yet, the first prototype flew on 30 July 1954 with a non-afterburning engine, an Armstrong Siddeley Sapphire Sa.6 with 8,000 lbf (35.59 kN). In spite of this lack of power the aircraft nevertheless nearly reached Mach 1 in its maiden flight. The second prototype, equipped with the intended Sapphire Sa.7 afterburning engine with 11,000 lbf (48.9 kN) thrust engine, showed the aircraft’s full potential. The Wasp turned out to have very good handling, and the RAF officially ordered sixty Folland Fo-145 day-fighters under the designation “Wasp F.Mk.1”. The only changes from the prototypes were small leading-edge extensions at the wing roots, improving low speed handling, esp. during landings and at high angles of incidence in flight.

 

Most Wasps were delivered to RAF Germany frontline units, including No. 20 and 92 Squadrons based in Northern Germany. However, the Wasp’s active service did not last long, because technological advancements quickly rendered the aircraft obsolete in its original interceptor role. The Wasp’s performance had not turned out as significantly superior to the Hunter as expected. Range was rather limited, and the aircraft turned out to be underpowered, since the reheated Sapphire Sa6 did not develop as much power as expected. The AI.Mk.20 radar was rather weak and capricious, too, and the Firestreak was an operational nightmare. The missile was, due to its solid Magpie rocket motor and the ammonia coolant for the IR seeker head, highly toxic and RAF armorers had to wear some form of CRBN protection to safely mount the missile onto an aircraft. Furthermore, unlike modern missiles, Firestreak’s effectiveness was very limited since it could only be fired outside cloud - and over Europe or in winter, skies were rarely clear.

 

Plans for a second production run of the Folland Wasp with a more powerful Sapphire Sa7R engine with a raised thrust of 12,300 lbf (54.7 kN) and updated avionics were not carried out. During the 1960s, following the successful introduction of the supersonic English Electric Lightning in the interceptor role, the Wasp, as well as the older but more prosperous and versatile Hunter, transitioned to being operated as a fighter-bomber, advanced trainer and for tactical photo reconnaissance missions.

This led to a limited MLU program for the F.Mk.1s and conversions of the remaining airframes into two new variants: the new main version was the GR.Mk.2, a dedicated CAS/ground attack variant, which had its radar removed and replaced with ballast, outwardly recognizable through a solid metal nose which replaced the original fiberglass radome. Many of these machines also had two of the 30mm guns removed to save weight. Furthermore, a handful Wasps were converted into PR.Mk.3s. These had as set of five cameras in a new nose section with various windows, and all the guns and the ammunition bay were replaced with an additional fuel tank, operating as pure, unarmed reconnaissance aircraft. When Folland was integrated into the Hawker Siddeley Group in 1963 the aircraft’s official name was changed accordingly, even though the Folland name heritage persisted.

 

Most of these aircraft remained allocated to RAF Germany units and retired towards the late Sixties, but four GR.Mk.2s were operated by RAF No. 57 (Reserve) Squadron and based at No. 3 Flying Training School at Cranwell, where they were flown as adversaries in dissimilar aerial combat training. The last of the type was withdrawn from service in 1969, but one aircraft remained flying with the Aeroplane and Armament Experimental Establishment at Boscombe Down until 24 January 1975.

  

General characteristics:

Crew: 1

Length: 45 ft 10.5 in (13.983 m)

Wingspan: 31 ft 7.5 in (9.639 m)

Height: 13 ft 2.75 in (4.0323 m)

Wing area: 250 sq ft (23 m2)

Empty weight: 13,810 lb (6,264 kg)

Gross weight: 21,035 lb (9,541 kg)

Max takeoff weight: 23,459 lb (10,641 kg)

 

Powerplant:

1× Armstrong Siddeley Sapphire Sa.6, producing 7,450 lbf (33.1 kN) thrust at 8,300 rpm,

military power dry, and 11,000 lbf (48.9 kN) with afterburner

 

Performance:

Maximum speed: 631 kn (726 mph, 1,169 km/h) / M1.1 at 35,000 ft (10,668 m)

654 kn (753 mph; 1,211 km/h) at sea level

Cruise speed: 501 kn (577 mph, 928 km/h)

Range: 1,110 nmi (1,280 mi, 2,060 km)

Service ceiling: 49,000 ft (15,000 m)

Rate of climb: 16,300 ft/min (83 m/s)

Wing loading: 84 lb/sq ft (410 kg/m2)

Thrust/weight: 0.5

 

Armament:

4× 30 mm (1.18 in) ADEN cannon, 125 rounds per gun

4× underwing hardpoints for a total external ordnance of 4.000 lb, including Firestreak AAMs,

SNEB pods, bombs of up to 1.000 lb caliber or two 125 imp gal (570 l) drop tanks

  

The kit and its assembly

This kit travesty is a remake of a simple but brilliant idea of fellow modeler chrisonord at whatifmodellers’com (www.whatifmodellers.com/index.php?topic=48434.msg899420#m...), who posted his own build in late 2020: a Grumman Tiger in standard contemporary RAF colors as Folland Wasp GR.Mk.2. The result looked like a highly credible “big brother” or maybe successor of Folland’s diminutive Midge/Gnat fighter, something in the Hawker Hunter’s class. I really like the idea a lot and decided that it was, one and a half years later, to build my personal interpretation of the subject – also because I had a Hasegawa F11F kit in The Stash™ without a proper plan.

 

The Tiger was built basically OOB – a simple and straightforward affair that goes together well, just the fine, raised panel lines show the mould’s age. The only changes I made: the arrester hook disappeared under PSR, small stabilizer fins (from an Italeri BAe Hawk) were added under the tail section, and I replaced the Tiger’s rugged twin wheel front landing gear with a single wheel alternative, left over from a Matchbox T-2 Buckeye. On the main landing gear, the rearward-facing stabilizing struts were deleted (for a lighter look of a land-based aircraft) and their wells filled with putty. A late modification were additional swing arms for the main landing gear, though: once the kit could sit on its own three feet, the stance was odd and low, esp. under the tail – probably due to the new front wheel. As a remedy I glued additional swing arm elements, made from 1mm steel wire, under the original struts, what moved the main wheel a little backwards and raised the main landing gear my 1mm. Does not sound like much, but it was enough to lift the tail and give the aircraft a more convincing stance and ground clearance.

 

The area-ruled drop tanks and their respective pylons were taken from the Hasegawa kit. For a special “British” touch – because the Tiger had a radome (into which no radar was ever fitted, though) – I added a pair of Firestreak AAMs on the outer underwing stations, procured from a Gomix Gloster Javelin (which comes with four of these, plus pylons).

  

Painting and markings:

Since the RAF theme was more or less settled, paintwork revolved around more or less authentical colors and markings. The Wasp received a standard RAF day fighter scheme from the late Fifties, with upper camouflage in RAF Dark Green/Dark Sea Grey and Light Aircraft Grey undersides with a low waterline. I used Humbrol 163, 106 and 166, respectively – Ocean Grey was used because I did not have the proper 164 at hand, but 106 also offered the benefit of a slightly better contrast to the murky Dark Green. A black ink washing was applied plus some panel post-shading. The silver leading edges on wings, stabilizers and fin were created with decal sheet material, avoiding the inconvenience of masking.

 

The cockpit interior was painted in a very dark grey (Revell 09, Anthracite) while the landing gear, wheels and wells received a greyish-metallic finish (Humbrol 56, Aluminum Dope). The air intakes’ interior became bright aluminum (Revell 99), the area around the jet nozzle was painted with Revell 91 (Iron metallic) and later treated with graphite for a dark metallic shine. The drop tanks were camouflaged, the Firestreaks became white so that they would stand out well and add to a certain vintage look.

 

The decals were a mix from various sources. The No. 20 Squadron badges and the Type D high-viz roundels on the wings were left over from an Airfix Hawker Hunter. The fuselage roundels came from an Italeri BAe Hawk sheet, IIRC. The bent fin flash, all the stencils as well as the serial code (which was puzzled together from two real serials and was AFAIK not allocated to any real RAF aircraft) came from an Xtradecal Supermarine Swift sheet. The individual red “B” letter came from a Matchbox A.W. Meteor night fighter.

 

Finally, the kit was sealed with matt acrylic varnish – I considered a glossy finish, since this was typical for RAF aircraft in the Fifties, but eventually just gave the radome a light shine.

  

Basically a simple project, and quickly done in just a couple of days. However, chrisonord’s great eye for similarities makes this “Tiger in disguise” a great fictional aircraft model with only little effort, it’s IMHO very convincing. And the RAF colors and markings suit the F11F very well.

I struggle a lot with feeling capable and competent, especially when it comes to taking on a new project or something where people are counting on me to deliver. I could have done a similar task/project a hundred times before and been highly successful, but it doesn't matter, I worry that this will be the time that I fail. I am my own worst enemy and instead of remembering that I CAN do this (whatever this may be), I needlessly cause myself a lot of stress and anxiety worrying that I can't.

Perhaps I need to wear this name tag every day to remind myself that, yes I CAN!

 

52 of YOU

+++ DISCLAIMER +++

Nothing you see here is real, even though the conversion or the presented background story might be based on historical facts. BEWARE!

  

Some background:

The McDonnell Douglas (now Boeing) T-45 Goshawk was a highly modified version of the BAe Hawk land-based training jet aircraft. Manufactured by McDonnell Douglas (now Boeing) and British Aerospace (now BAe Systems), the T-45 was used by the United States Navy and the United States Marine Corps (USMC) as an aircraft carrier-capable trainer.

The Goshawk's origins began in the mid-1970s, when the US Navy began looking for a single aircraft replacement for both its T-2 and TA-4 jet trainers. The US Navy started the VTXTS advanced trainer program in 1978. Several companies made submissions, e. g. North American or Northrop/Vought. Due to the size of the potential contract, European companies made submissions, too, including a navalized Alpha Jet from Dassault/Dornier and a fully carrier-capable version of the BAe Hawk Mk.60, mutually proposed by British Aerospace (BAe) and McDonnell Douglas (MDC). The latter eventually won the competition and BAe and MDC were awarded the T-45 contract in 1981.

 

The Hawk had not been designed for carrier operations and numerous modifications were required to make it suitable for use on carriers. These included improvements to the low-speed handling characteristics and a reduction in the approach speed. It was found that the aircraft was apt to stall at the low approach speed required. Modifications were designed by BAe in England; most notably a simple slat system was devised, operated by an actuator and linkage mechanism to fit into the small space available. Strakes were also added on the fuselage to improve airflow. Other changes were a strengthened airframe, a more robust and wider landing gear with a two-wheel nose landing gear, a catapult tow bar attachment and an arresting hook. The modified aircraft was christened “Goshawk”, flew in 1988 for the first time and became operational in 1991.

 

Beyond being a naval trainer the T-45 was also adapted for first-line duty with strike capabilities, in the form of the OA-45 for the USMC. The role of this aircraft dated back to the Vietnam War when twenty-three A-4 two-seaters were converted into OA-4Ms for “FastFAC” (Fast Forward Air Controller) missions, in order to control interdiction sorties dedicated to shaping the battlefield for future operations. Basically, the OA-4M was a TA-4F equipped with A-4M electronics. The most visible and characteristic change was the fitting of the A-4M’s dorsal electronics hump, neatly faired into the rear of the two-seat canopy. The nose sensor group of the OA-4M was basically the same as that of the A-4M, but the Angle/Rate Bombing system was not installed as it would not be needed.

 

When the T-45 was introduced in the early Nineties, the USMCs OA-4Ms had reached the end of their service life and the USMC started looking for a replacement, wanting a comparable, light and fast fixed-wing aircraft. The USMC did not accept the LTV A-7 as an A-4 replacement (even though a two-seater version was available), because it was already dated, too, and not part of the USMC inventory. The USMC's A-4Ms were supposed to be replaced by the VTOL AV-8 by the mid-nineties, but the AV-8, even as a two-seater, was deemed unsuitable for FFAC duties. The new T-45 looked like a good and economical alternative with future potential, since the airframe was brand new and the type's infrastructure was fully established, so that a small number of specialized aircraft could easily be supported without much extra cost.

 

With fresh experience from the 1st Gulf War in 1990-91 the decision was made to buy 25 extra T-45A airframes and convert them to OA-45A standard. Most important change were modified wings, using structures and systems from the BAe Hawk 100 series. While the T-45 only had two underwing and a single ventral hardpoint, the OA-45A featured a total of seven: four underwing and one ventral hardpoints, plus wingtip stations for defensive air-to-air missiles. Upgraded avionics allowed the deployment of a wide range of external stores, including air-to-ground missiles and rocket launchers, a reconnaissance pod, retarded and free-fall bombs of up to 1,000 pounds (450 kg) caliber, runway cratering, anti-personnel and light armor bombs, cluster bombs, practice bombs as well as external fuel tanks and ECM pods. This was a vital asset, since Desert Storm had proved that FFAC aircraft had to have an offensive capability to handle targets of opportunity on their own, when no air assets to control were available. A total ordnance load of up to 6,800 lb (3,085 kg) was possible, even though the aircraft was not supposed to play an offensive role and rather act from a distance, relying on its small size and agility.

 

Communication modifications for the FastFAC role included a KY-28 secure voice system, an ARC-159 radio and an ARC-114 VHF radio. Similar to the Skyhawk, a hump behind the cockpit had to be added to make room for the additional electronic equipment and a heat exchanger. Other additions were a continuous-wave Doppler navigation radar under a shallow ventral radome underneath the cockpit, a ground control bombing system, an APN-194 altimeter, an ALR-45 radar warning suite, a retrofitted, fixed midair refueling probe and cockpit armor plating that included Kevlar linings on the floor and the lower side walls as well as externally mounted armor plates for the upper areas.

 

VMA-131 of Marine Aircraft Group 49 (the Diamondbacks) retired its last four OA-4Ms on 22 June 1994, and the new OA-45A arrived just in time to replace the venerable Skyhawk two-seaters in the FastFAC role. Trainer versions of the Skyhawk remained in Navy service, however, finding a new lease on life with the advent of "adversary training". OA-45A deliveries were finished in 1996 and the 25 aircraft were distributed among the newly established Marine Aviation Logistics Squadron (MALS, formerly Headquarters & Maintenance Squadron/H&MS) 12 & 13. The USMC crews soon nicknamed their new mounts "GosHog", to underlöine ist offensive capabilities and to set themselves apart from the USN's "tame" trainers. Even though thos name was never officially approved it caught on quickly.

 

After initial experience with the new aircraft and in the wake of technological advances, the USMC decided to upgrade the OA-45As in 2000 to improve its effectiveness and interaction capabilities with ground troops. This primarily resulted in the addition of a forward-looking infrared camera laser in the aircraft’s nose section, which enabled the aircraft to execute all-weather/night reconnaissance and to illuminate targets for laser-guided infantry shells or ordnance launched by the OA-45 itself or by other aircraft. Through this measure the OA-45 became capable of carrying and independently deploying light laser-guided smart weapons like the GBU-12 and -16 “Paveway II” glide bombs or the laser-guided AGM-65E “Maverick” variant. The update was gradually executed during regular overhauls in the course of 2001 and 2002 (no new airframes were built/converted), the modified machines received the new designation OA-45B.

 

After this update phase, the OA-45Bs were deployed in several global conflicts and saw frequent use in the following years. For instance, MALS 13 used its OA-45Bs operationally for the first time in October 2002 when the squadron was tasked with providing support to six AV-8B Harrier aircraft in combat operations in Afghanistan during Operation Enduring Freedom. This mission lasted until October 2003, four aircraft were allocated and one OA-45B was lost during a landing accident.

On 15 January 2003, MALS 13 embarked 205 Marines and equipment aboard the USS Bonhomme Richard in support of combat operations in Southwest Asia during Operation Southern Watch. Four OA-45Bs successfully supported these troops from land bases, marking targets and flying reconnaissance missions.

Furthermore, six MALS 13 OA-45Bs took actively part in Operation Iraqi Freedom from Al Jaber Air Base, Kuwait, and An Numiniyah Expeditionary Air Field, Iraq, where the aircraft worked closely together with the advancing ground troops of the USMC’s 15th Marine Expeditionary Unit. They successfully illuminated targets for US Navy fighter bombers, which were launched from USS Abraham Lincoln (CVN-72) in the Persian Gulf, and effectively guided these aircraft to their targets. Two OA-45Bs were lost during this conflict, one through enemy MANPADS, the other through friendly AA fire. In late May 2003 the surviving machines and their crews returned to MCAS Yuma.

 

On 16 March 2007, the 200th T-45 airframe was delivered to the US Navy. From this final batch, six airframes were set aside and modified into OA-45Bs in order to fill the losses over the past years.

Later T-45 production aircraft were built with enhanced avionics systems for a heads-up display (HUD) and glass cockpit standard, while all extant T-45A aircraft were eventually converted to a T-45C configuration under the T-45 Required Avionics Modernization Program (T-45 RAMP), bringing all aircraft to same HUD plus glass cockpit standard. These updates, esp. concerning the cockpit, were introduced to the OA-45Bs, too, and they were re-designated again, now becoming OA-45Cs, to reflect the commonality with the Navy’s Goshawk trainers. Again, these modifications were gradually introduced in the course of the OA-45s’ normal maintenance program.

 

In 2007, an engine update of the whole T-45 fleet, including the OA-45s, with the Adour F405-RR-402 was considered. This new engine was based on the British Adour Mk 951, designed for the latest versions of the BAe Hawk and powering the BAe Taranis and Dassault nEUROn UCAV technology demonstrators. The Adour Mk 951 offered 6,500 lbf (29 kN) thrust and up to twice the service life of the F405-RR-401. It featured an all-new fan and combustor, revised HP and LP turbines, and introduced Full Authority Digital Engine Control (FADEC). The Mk 951 was certified in 2005, the F405-RR-402 derived from it was certified in 2008, but it did not enter service due to funding issues, so that this upgrade was not carried out.

 

The final delivery of the 246th T-45 airframe took place in November 2009, and both T-45 and the OA-45 "GosHog" are supposed to remain in service until 2035.

  

General characteristics:

Crew: 2 (pilot, observer)

Length: 39 ft 4 in (11.99 m)

Wingspan: 30 ft 10 in (9.39 m)

Height: 13 ft 5 in (4.08 m)

Wing area: 190.1 ft² (17.7 m²)

Empty weight: 10,403 lb (4,460 kg)

Max. takeoff weight: 14,081 lb (6,387 kg)

 

Powerplant:

1× Rolls-Royce Turbomeca F405-RR-401 (Adour) non-afterburning turbofan with 5,527 lbf (26 kN)

 

Performance:

Maximum speed: Mach 2 (2,204 km/h (1,190 kn; 1,370 mph) at high altitude

Combat radius: 800 km (497 mi, 432 nmi)

Ferry range: 3,200 km (1,983 mi) with drop tanks

Service ceiling: 15,240 m (50,000 ft)

Wing loading: 283 kg/m² (58 lb/ft²)

Thrust/weight: 0.97

Maximum g-load: +9 g

 

Armament:

No internal gun; seven external hardpoints (three on each wing and one under fuselage)

for a wide range of ordnance of up to 6,800 lb (3,085 kg), including up to six AIM-9 Sidewinder for

self-defense, pods with unguided rockets for target marking or ECM pods, but also offensive weapons

of up to 1.000 lb (454 kg) weight, including iron/cluster bombs and guided AGM-65, GBU-12 and -16.

  

The kit and its assembly:

This fictional T-45 variant is actually the result of a long idea evolution, and simply rooted in the idea of a dedicated OA-4M replacement for the USMC; in real life, the FFAC role has been transferred to F-18 two-seaters, though, but the T-45 appeared like a sound alternative to me.

 

There's only one T-45 kit available, a dubious T-45A from Italeri with poor wings and stabilizers. Wolfpack also offers a T-45, but it’s just a re-boxing of the Italeri kit with some PE parts and a price tag twice as big – but it does not mend the original kit’s issues… After reading the A-4 Skyhawk book from the French "Planes & Pilots" series, I was reminded of the USMC's special OA-4M FAC two-seaters (and the fact that it is available in kit form from Italeri and Hasegawa), and, cross-checking the real-world timeline of the T-45, I found that it could have been a suitable successor. The ide of the USMC’s OA-45 was born! :D

 

Building-wise the Italeri T-45 remained close to OOB, even though I transplanted several parts from an Italeri BAe Hawk Mk. 100 to create a different look. I modified the nose with the Mk. 100’s laser fairing and added some radar warning sensor bumps. This transplantation was not as easy as it might seem because the T-45’s nose is, due to the different and more massive front landing gear quite different from the Hawk’s. Took some major PSR to integrate the laser nose.

An ALR-45 “hot dog” fairing from a late A-4M (Italeri kit) was added to the fin, together with a small styrene wedge extending the fin’s leading edge. This small detail markedly changes the aircraft’s look. I furthermore added a refueling probe, scratched from coated wire and some white glue, as well as a low “camel back” fairing behind the cockpit, created from a streamlined bomb half with air outlets for an integrated heat exchanger. Blade antennae were relocated and added. A shallow bump for the Doppler radar was added under the fuselage behind the landing gear well – left over from an Airfix A-4B (from an Argentinian A-4P, to be correct, actually a dorsal fairing).

 

On the wings, a tailored pair of pylons and wing tip launch rails from the Italeri BAe Hawk Mk. 100 kit were added, too, as well as the donor kit’s pair of Sidewinders. The rest of the ordnance consists of drop tanks and LAU-19 pods for target marking missiles. The tanks were taken from the Hawk Mk. 100 kit, too, the rocket launchers came from an Italeri NATO aircraft weapons set. The centerline position carries an ALQ-131 ECM pod from a Hasegawa US aircraft weapons set on a pylon from the scrap box.

  

Painting and markings:

The low-viz idea prevailed, since I had some leftover OA-4M decals from Italeri kits in store, as well as some other suitable low-viz decals from a Revell A-4F kit. However, an all-grey livery was IMHO not enough, and when I came across a picture of a USN low-viz A-7E with an improvised desert camouflage in sand and reddish brown applied over the grey (even partly extending over its markings) from Operation Iraqi Freedom, I had that extra twist that would set the OA-45 apart. MALS-13 was chosen as operator because I had matching codes, and, as another benefit, the unit had actually been deployed overseas during the 2003 Iraq War, so that the whif’’s time frame was easily settled, adding to its credibility.

 

The livery was built up just like on the real aircraft: on top of a basic scheme in FS 36320 and 36375 (Humbrol 128 and 127) with a slightly darker anti-glare panel in front of the cockpit (FS 35237, I used Revell 57 as a slightly paler alternative) I applied the low-viz marking decals, which were protected with a coat of acrylic varnish. Next, additional desert camouflage was added with dry-brushed sand and millitary brown (supposedly FS 33711 and 30400 in real life, I used, after consulting pictures of aircraft from both Gulf Wars, Humbrol 103 (Cream) and 234 (Dark Flesh). They were applied with a kind of a dry-brushing technique, for a streaky and worn look, leaving out the codes and other markings. The pattern itself was inspired by an USMC OV-10 Bronco in desert camouflage from the 1st Gulf War.

On top of that a black ink washing was applied. Once things had thoroughly dried over night, I wet-sanded the additional desert camouflage away, carefully from front to back, so that the edges became blurred and the underlying grey became visible again.

 

The cockpit interior was painted in standard Dark Gull Grey (Humbrol 140), while the air intakes and the landing gear became white, the latter with red trim on the covers’ edges – just standard. Finally, the model was sealed with a coat of matt acrylic varnish (Italeri).

  

The upgraded T-45 is an interesting result. The add-ons suit the aircraft, which already looks sturdier than its land-based ancestor, well. The improvised desert paint scheme with the additional two-tone camouflage over the pale grey base really makes the aircraft an unusual sight, adding to its credibility.

Hardware-wise I am really happy how the added dorsal hump blends into the overall lines – in a profile view it extends the canopy’s curve and blends into the fin, much like the A-4F/M’s arrangement. And the modified fin yields a very different look, even though not much was changed. The T-45 looks much beefier now, and from certain angles really reminds of the OA-4M and sometimes even of a diminutive Su-25?

+++ DISCLAIMER +++

Nothing you see here is real, even though the conversion or the presented background story might be based historical facts. BEWARE!

  

The KAI T-50 Golden Eagle (골든이글) is a family of South Korean supersonic advanced trainers and light combat aircraft, developed by Korea Aerospace Industries (KAI) with Lockheed Martin. The T-50 is South Korea's first indigenous supersonic aircraft and one of the world's few supersonic trainers.

 

The T-50 program started in the late Nineties and was originally intended to develop an indigenous trainer aircraft capable of supersonic flight, to train and prepare pilots for the KF-16 and F-15K, replacing trainers such as T-38 and A-37 that were then in service with the ROKAF. Prior South Korean aircraft programs include the turboprop KT-1 basic trainer produced by Daewoo Aerospace (now part of KAI), and license-manufactured KF-16.

 

The mother program, code-named KTX-2, began in 1992, but the Ministry of Finance and Economy suspended the original project in 1995 due to financial constraints. The basic design of the aircraft was set by 1999, and eventually the development of the aircraft was funded 70% by the South Korean government, 17% by KAI, and 13% by Lockheed Martin.

 

In general, the T-50 series of aircraft closely resembles the KF-16 in configuration, but it actually is a completely new design: the T-50 is 11% smaller and 23% lighter than an F-16, and in order to create enough space for the two-seat cockpit, the air intake was bifurcated and placed under the wing gloves, resembling the F/A-18's layout.

 

The aircraft was formally designated as the T-50 'Golden Eagle' in February 2000, the T-50A designation had been reserved by the U.S. military to prevent it from being inadvertently assigned to another aircraft model. Final assembly of the first T-50 took place between 15 January and 14 September 2001. The first flight of the T-50 took place in August 2002, and initial operational assessment from 28 July to 14 August 2003.

 

The trainer has a cockpit for two pilots in a tandem arrangement, both crew members sitting in "normal" election seats, not in the F-16's reclined position. The high-mounted canopy is applied with stretched acrylic, providing the pilots with good visibility, and has been tested to offer the canopy with ballistic protection against 4-lb objects impacting at 400 knots.

 

The ROKAF, as original development driver, placed an initial production contract for 25 T-50s in December 2003, with aircraft scheduled to be delivered between 2005 and 2009. Original T-50 aircraft were equipped with the AN/APG-67(v)4 radar from Lockheed Martin. The T-50 trainer is powered by a GE F404 engine built under license by Samsung Techwin. Under the terms of the T-50/F404-102 co-production agreement, GE provides engine kits directly to Samsung Techwin who produces designated parts as well as performing final engine assembly and testing.

 

The T-50 program quickly expanded beyond a pure trainer concept to include the TA-50 armed trainer aircraft, as well as the FA-50 light attack aircraft, which has already similar capabilities as the multirole KF-16. Reconnaissance and electronic warfare variants were also being developed, designated as RA-50 and EA-50.

 

The TA-50 variant is a more heavily armed version of the T-50 trainer, intended for lead-in fighter training and light attack roles. It is equipped with an Elta EL/M-2032 fire control radar and designed to operate as a full-fledged combat platform. This variant mounts a lightweight three-barrel cannon version of the M61 Vulcan internally behind the cockpit, which fires linkless 20 mm ammunition. Wingtip rails can accommodate the AIM-9 Sidewinder missile, a variety of additional weapons can be mounted to underwing hardpoints, including precision-guided weapons, air-to-air missiles, and air-to-ground missiles. The TA-50 can also mount additional utility pods for reconnaissance, targeting assistance, and electronic warfare. Compatible air-to-surface weapons include the AGM-65 Maverick missile, Hydra 70 and LOGIR rocket launchers, CBU-58 and Mk-20 cluster bombs, and Mk-82, -83, and -84 general purpose bombs.

 

Among the operators of the TA-50 are the Philippines, Thailand and the ROKAF, and the type has attracted a global interest, also in Europe. The young Republic of Scotland Air Corps (locally known as Poblachd na h-Alba Adhair an Airm) chose, soon after the country's independence from the United Kingdom, after its departure from the European Union in 2017, the TA-50 as a complement to its initial procurements and add more flexibility to its small and young air arm.

 

According to a White Paper published by the Scottish National Party (SNP) in 2013, an independent Scotland would have an air force equipped with up to 16 air defense aircraft, six tactical transports, utility rotorcraft and maritime patrol aircraft, and be capable of “contributing excellent conventional capabilities” to NATO. Outlining its ambition to establish an air force with an eventual 2,000 uniformed personnel and 300 reservists, the SNP stated the organization would initially be equipped with “a minimum of 12 interceptors in the Eurofighter/Typhoon class, based at Lossiemouth, a tactical air transport squadron, including around six [Lockheed Martin] C-130J Hercules, and a helicopter squadron”.

 

According to the document, “Key elements of air forces in place at independence, equipped initially from a negotiated share of current UK assets, will secure core tasks, principally the ability to police Scotland’s airspace, within NATO.” An in-country air command and control capability would be established within five years of a decision in favor of independence, it continues, with staff also to be “embedded within NATO structures”.

This plan was immediately set into action after the country's independence in late 2017 with the purchase of twelve refurbished Saab JAS 39A Gripen interceptors for Quick Reaction Alert duties and upgraded, former Swedish Air Force Sk 90 trainers for the RoScAC. But these second hand machines were just the initial step in the mid-term procurement plan.

 

The twelve KAI TA-50 aircraft procured as a second step were to fulfill the complex requirement for a light and cost-effective multi-purpose aircraft that could be used in a wide variety of tasks: primarily as an advanced trainer for supersonic flight and as a trainer for the fighter role (since all Scottish Gripens were single seaters and dedicated to the interceptor/air defense role), but also as a light attack and point defense aircraft.

 

Scotland was offered refurbished F-16C and Ds, but this was declined as the type was deemed to be too costly and complex. Beyond the KAI T-50, the Alenia Aermacchi M-346 Master and the BAe Hawk were considered, too, but, eventually, a modified TA-50 that was tailored to the RoScAC’s procurement plans was chosen by the Scottish government.

 

In order to fulfill the complex duty profile, the Scottish TA-50s were upgraded with elements from the FA-50 attack aircraft. They possess more internal fuel capacity, enhanced avionics, a longer radome and a tactical datalink. Its EL/M-2032 pulse-Doppler radar has been modified so that it offers now a range two-thirds greater than the TA-50's standard radar. It enables the aircraft to operate in any weather, detect surface targets and deploy AIM-120 AAMs for BVR interceptions. The machines can also be externally fitted with Rafael's Sky Shield or LIG Nex1's ALQ-200K ECM pods, Sniper or LITENING targeting pods, and Condor 2 reconnaissance pods to further improve the machine’s electronic warfare, reconnaissance, and targeting capabilities.

 

Another unique feature of the Scottish Golden Eagle is its powerplant: even though the machines are originally powered by a single General Electric F404 afterburning turbofan and designed around this engine, the RoScAC TF-50s are powered by a Volvo RM12 low-bypass afterburning turbofan. These are procured and serviced through Saab in Sweden, as a part of the long-term collaboration contract for the RoScAC’s Saab Gripen fleet. This decision was taken in order to decrease overall fleet costs through a unified engine.

 

The RM12 is a derivative of the General Electric F404-400. Changes from the standard F404 includes greater reliability for single-engine operations (including more stringent birdstrike protection) and slightly increased thrust. Several subsystems and components were also re-designed to reduce maintenance demands, and the F404's analogue Engine Control Unit was replaced with the Digital Engine Control – jointly developed by Volvo and GE – which communicates with the cockpit through the digital data buses and, as redundancy, mechanical calculators controlled by a single wire will regulate the fuel-flow into the engine.

 

Another modification of the RoScAC’s TA-50 is the exchange of the original General Dynamics A-50 3-barrel rotary cannon for a single barrel Mauser BK-27 27mm revolver cannon. Being slightly heavier and having a lower cadence, the BK-27 featured a much higher kinetic energy, accuracy and range. Furthermore, the BK-27 is the standard weapon of the other, Sweden-built aircraft in RoScAC service, so that further synergies and cost reductions were expected.

 

The Scottish Department of National Defense announced the selection of the TA-50 in August 2018, after having procured refurbished Saab Sk 90 and JAS 39 Gripen from Sweden as initial outfit of the country's small air arm with No. 1 Squadron based at Lossiemouth AB.

 

Funding for the twelve aircraft was approved by Congress on September 2018 and worth € 420 mio., making the Golden Eagle the young country’s first brand new military aircraft. Deliveries of the Golden Hawk TF.1, how the type was officially designated in Scottish service, began in November 2019, lasting until December 2020.

The first four Scottish Golden Hawk TF.1 aircraft were allocated to the newly established RoScAC No. 2 Squadron, based at Leuchars, where the RoScAC took control from the British Army. The latter had just taken over the former air base from the RAF in 2015, losing its “RAF air base” status and was consequentially re-designated “Leuchars Station”, primarily catering to the Royal Scots Dragoon Guards who have, in the meantime, become part of Scotland’s Army Corps. The brand new machines were publically displayed on the shared army and air corps facility in the RoScAC’s new paint scheme on 1st of December 2019 for the first time, and immediately took up service.

 

General characteristics:

Crew: 2

Length: 13.14 m (43.1 ft)

Wingspan (with wingtip missiles): 9.45 m (31 ft)

Height: 4.94 m (16.2 ft)

Wing area: 23.69 m² (255 ft²)

Empty weight: 6,470 kg (14,285 lb)

Max. takeoff weight: 12,300 kg (27,300 lb)

 

Powerplant:

1× Volvo RM12 afterburning turbofan, rated at 54 kN (12,100 lbf) dry thrust

and 80.5 kN (18,100 lbf) with afterburner

 

Performance:

Maximum speed: Mach 1.5 (1,640 km/h, 1,020 mph at 9,144 m or 30,000 ft)

Range: 1,851 km (1,150 mi)

Service ceiling: 14,630 m (48,000 ft)

Rate of climb: 198 m/s (39,000 ft/min)

Thrust/weight: 0.96

Max g limit: -3 g / +8 g

 

Armament:

1× 27mm Mauser BK-27 revolver cannon with 120 rounds

A total of 7 hardpoints (4 underwing, 2 wingtip and one under fuselage)

for up to 3,740 kg (8,250 lb) of payload

  

The kit and its assembly:

A rare thing concerning my builds: an alternative reality whif. A fictional air force of an independent Scotland crept into my mind after the hysterical “Brexit” events in 2016 and the former (failed) public vote concerning the independence of Scotland from the UK. What would happen to the military, if the independence would take place, nevertheless, and British forces left the country?

 

The aforementioned Scottish National Party (SNP) paper from 2013 is real, and I took it as a benchmark. Primary focus would certainly be set on air space defense, and the Gripen appears as a good and not too expensive choice. The Sk 90 is a personal invention, but would fulfill a good complementary role.

Nevertheless, another multi-role aircraft would make sense as an addition, and both M-346 and T-50 caught my eye (Russian options were ruled out due to the tense political relations), and I gave the TA-50 the “Go” because of its engine and its proximity to the Gripen.

 

The T-50 really looks like the juvenile offspring from a date between an F-16 and an F-18. There’s even a kit available, from Academy – but it’s a Snap-Fit offering without a landing gear but, as an alternative, a clear display that can be attached to the engine nozzle. It also comes with stickers instead of waterslide decals. This sounds crappy and toy-like, but, after taking a close look at kit reviews, I gave it a try.

 

And I am positively surprised. While the kit consists of only few parts, moulded in the colors of a ROCAF trainer as expected, the surfaces have minute, engraved detail. Fit is very good, too, and there’s even a decent cockpit that’s actually better than the offering of some “normal” model kits. The interior comes with multi-part seats, side consoles and dashboards that feature correctly shaped instrument details (no decals). The air intakes are great, too: seamless, with relatively thin walls, nice!

 

So far, so good. But not enough. I could have built the kit OOB with the landing gear tucked up, but I went for the more complicated route and trans-/implanted the complete landing gear from an Intech F-16, which is available for less than EUR 5,- (and not much worth, to be honest). AFAIK, there’s white metal landing gear for the T-50 available from Scale Aircraft Conversions, but it’s 1:48 and for this set’s price I could have bought three Intech F-16s…

 

But back to the conversion. This landing gear transplantation stunt sounds more complicated as it actually turned out to be. For the front wheel well I simply cut a long opening into the fuselage and added inside a styrene sheet as a well roof, attached under the cockpit floor.

For the main landing gear I just opened the flush covers on the T-50 fuselage, cut out the interior from the Intech F-16, tailored it a little and glued it into its new place.

 

This was made easy by the fact that the T-50 is a bit smaller than the F-16, so that the transplants are by tendency a little too large and offer enough “flesh” for adaptations. Once in place, the F-16 struts were mounted (also slightly tailored to fit well) and covers added. The front wheel cover was created with 0.5 mm styrene sheet, for the main covers I used the parts from the Intech F-16 kit because they were thinner than the leftover T-50 fuselage parts and feature some surface detail on the inside. They had to be adapted in size, though. But the operation worked like a charm, highly recommended!

 

Around the hull, some small details like missing air scoops, some pitots and antennae were added. In a bout of boredom (while waiting for ordered parts…) I also added static dischargers on the aerodynamic surfaces’ trailing edges – the kit comes with obvious attachment points, and they are a small detail that improves the modern look of the T-50 even more.

 

Since the Academy kit comes clean with only a ventral drop tank as ordnance, underwing pylons from a SEPECAT Jaguar (resin aftermarket parts from Pavla) and a pair of AGM-65 from the Italeri NATO Weapons set plus launch rails were added, plus a pair of Sidewinders (from a Hasegawa AAM set, painted as blue training rounds) on the wing tip launch rails.

Since the T-50 trainer comes unarmed, a gun nozzle had to be added – its position is very similar to the gun on board of the F-16, on the upper side of the port side LERX. Another addition are conformal chaff/flare dispensers at the fin’s base, adding some beef to the sleek aircraft.

  

Painting and markings:

I did not want a grey-in-grey livery, yet something “different” and rather typical or familiar for the British isles. My approach is actually a compromise, with classic RAF colors and design features inspired by camouflage experiments of the German Luftwaffe on F-4F Phantoms and Alpha Jets in the early Eighties.

 

For the upper sides I went for a classic British scheme, in Dark Green and Dark Sea Grey (Humbrol 163 and 164), colors I deem very appropriate for the Scottish landscape and for potential naval operations. These were combined with elements from late RAF interceptors: Barley Grey (Humbrol 167) for the flanks including the pylons, plus Light Aircraft Grey (Humbrol 166) for the undersides, with a relatively high waterline and a grey fin, so that a side or lower view would rather blend with the sky than the ground below.

 

Another creative field were the national markings: how could fictional Scottish roundels look like, and how to create them so that they are easy to make and replicate (for a full set for this kit, as well as for potential future builds…)? Designing and printing marking decals myself was an option, but I eventually settled for a composite solution which somewhat influenced the roundels’ design, too.

My Scottish roundel interpretationconsists of a blue disk with a white cross – it’s simple, different from any other contemporary national marking, esp. the UK roundel, and easy to create from single decal parts. In fact, the blue roundels were die-punched from blue decal sheet, and the cross consists of two thin white decal strips, cut into the correct length with the same stencil, using generic sheet material from TL Modellbau.

 

Another issue was the potential tactical code, and a small fleet only needs a simple system. Going back to a WWII system with letter codes for squadrons and individual aircraft was one option, but, IMHO, too complicated. I adopted the British single letter aircraft code, though, since this system is very traditional, but since the RoScAC would certainly not operate too many squadrons, I rather adapted a system similar to the Swedish or Spanish format with a single number representing the squadron. The result is a simple 2-digit code, and I adapted the German system of placing the tactical code on the fuselage, separated by the roundel. Keeping British traditions up I repeated the individual aircraft code letter on the fin, where a Scottish flag, a small, self-printed Fife coat-or-arms and a serial number were added, too.

 

The kit saw only light weathering and shading, and the kit was finally sealed with matt acrylic varnish (Italeri).

  

Creating this whif, based on an alternative historic timeline with a near future perspective, was fun – and it might spawn more models that circle around the story. A Scottish Sk 90 and a Gripen are certain options (and for both I have kits in the stash…), but there might also be an entry level trainer, some helicopters for the army and SAR duties, as well as a transport aircraft. The foundation has been laid out, now it’s time to fill Scotland’s history to come with detail and proof. ;-)

 

Besides, despite being a snap-fit kit, Academy’s T-50 is a nice basis, reminding me of some Hobby Boss kits but with less flaws (e .g. most of the interiors), except for the complete lack of a landing gear. But with the F-16 and Jaguar transplants the simple kit developed into something more convincing.

Collage postcard that I made and sent for a handmade postcard swap.

Waiting in the rain & in vain for 60103 Flying Scotsman at Ampthill Crossing 4/11/2017 (It was 25 minutes earlier than The British Rail Class 222 is a diesel multiple unit high-speed train capable of 125 mph (200 km/h). Twenty-seven units have been built in Belgium by Bombardier Transportation.

 

The Class 222 is similar to the Class 220 Voyager and Class 221 Super Voyager trains used by CrossCountry and Virgin Trains, but it has a different interior. The Class 222 trains have more components fitted under the floors to free up space within the body. Since 2009 East Midlands Trains has been the only train operating company using Class 222s.

All coaches are equipped with a Cummins QSK19 diesel engine of 750 hp (560 kW) at 1800 rpm.[2] This powers a generator, which supplies current to motors driving two axles per coach. Approximately 1,350 miles (2,170 km) can be travelled between each refuelling.

 

Class 222 have rheostatic braking using the motors in reverse to generate electricity which is dissipated as heat through resistors situated on the roof of each coach; this saves on brake pad wear.

 

In common with the Class 220s, B5000 lightweight bogies are used - these are easily recognisable since the entire outer surface of the wheel is visible, with inboard axle bearings.

 

The Class 222 are fitted with Dellner couplers,[3] as on Class 220 Voyager and Class 221 SuperVoyager trains,[3] though these units cannot work together in service because the Class 222 electrical connections are incompatible with the Class 220 and Class 221 trains.[3][clarification needed]

 

All Class 222 units are maintained at the dedicated Etches Park depot in Derby, just south of Derby station.

 

Formation[edit]

 

Seven car length Class 222 No. 222003 at London St Pancras

 

Five car length Class 222 No. 222016 at Bedford

Class 222 units are currently running in the following formations:

 

East Midlands Trains: seven cars with 236 standard seats and 106 first-class seats.

 

Coach A - Standard Class with driving cab and reservable space for two bikes

Coach B - Standard Class

Coach C - Standard Class

Coach D - Standard Class with Buffet counter

Coach F - First Class

Coach G - First Class

Coach H - First Class, kitchen and driving cab

East Midlands Trains: five cars with 192 standard seats and 50 first-class seats

 

Coach A - Standard Class with driving cab and reservable space for two bikes

Coach B - Standard Class

Coach C - Standard Class with Buffet counter

Coach D - Standard Class / First Class composite

Coach G - First Class, kitchen and driving cab

East Midlands Trains: four cars with 132 standard seats and 33 first-class seats

 

Coach A - Standard Class with driving cab and reservable space for two bikes

Coach B - Standard Class with Buffet counter

Coach D - Standard Class / First Class composite

Coach G - First Class, kitchen and driving cab

The four- and five-car units can be coupled to form 9/10-car services at peak times. When coupled together, coaches A-G are found in the front unit and the rear coaches become labelled J, K, L, M, N, with the first-class seats in coaches J and K.

 

Initially, the 23 units ordered for Midland Mainline were 4-car and 9-car. Over time these have been gradually modified to the current formations. The 4-car units ordered by Hull Trains had an option when constructed to be extended to 5-cars if required.[4]

East Midlands Trains has named the following Meridians:

 

Unit numberNameDate namedNamed byNotes

222 001The Entrepreneur Express22 September 2011Tim Shoveller, East Midlands Trains Managing DirectorNamed to kick off the start of the 2011 entrepreneur festival MADE

222 002The Cutlers' Company18 October 2011Pamela Liversidge, Master CutlerNamed to mark the successful partnership between East Midlands Trains and Sheffield

222 003Tornado24 March 2009Tim Shoveller, East Midlands Trains Managing DirectorDriving car 60163 named as it has the same number as Tornado

222 004Children's Hospital Sheffield26 February 2013Michael Vaughan, Charity PatonTo mark the successful partnership between East Midlands Trains and the Sheffield Children's Hospital

222 006The Carbon Cutter31 May 2011Philip Hammond, Transport SecretaryTo mark the introduction of eco-mode to the fleet

222 008Derby Etches Park13 September 2014David Horne, East Midlands Trains Managing DirectorNamed as part of the open day at Derby Etches Park

222 015175 Years of Derby's Railways 1839 - 201418 July 2014Paul Atterbury, Antiques Roadshow Expert and railway authorTo mark 175 years of railways in Derby

222 022Invest In Nottingham19 September 2011Jon Collins, leader of Nottingham City CouncilNamed to launch the 2011 Invest in Nottingham day

222 011Sheffield City Battalion 1914-191811 November 2014Ron Wiltshire, Royal British Legion representativeNamed to honour Sheffield City Battalion who fought in the World War I

 

East Midlands Trains Class 222/0 No. 222018 at Loughborough.

In 2008 further rearrangements were made to the sets: another carriage was removed from the eight-car Meridians, except for 222 007, which has been reduced to five cars.[6] The surplus coaches were then added to the remaining four-car Meridians to make six seven-car sets (222 001-222 006) and 17 five-car sets (222 007-222 023). This took place from March to October 2008; as part of the process, two first-class coaches removed from 222 007 were converted to standard class and part first class.

 

The seven-car trains are almost exclusively used on the fast services between London St Pancras and Sheffield. These do not operate the London St Pancras-Leeds, although the service is via Sheffield. The five-car trains are mainly used between London St Pancras and Sheffield, Nottingham or Corby on semi-fast services. The four-car trains supplement the five-car trains on these services.

 

In December 2008 the Class 222 Meridians started work on the hourly London St Pancras to Sheffield services, because they have faster acceleration than the High Speed Trains and so were able to reduce the Sheffield to London journey time by 12 minutes. The hourly Nottingham service was then transferred to High Speed Train running to cover for the Meridians now working the hourly Sheffield fast service.[7]

 

In February 2009, 222 101 and 222 102 transferred from Hull Trains to East Midlands Trains, and were quickly repainted in the East Midlands Trains white livery. 222 104 followed from Hull Trains later in the year. 222 103 followed a few months after 222 104 after repairs had been completed (see below). 222 103 has now been reinstated for service after two years for repairs after the unit fell from jacks at Bombardier, Crofton in early 2007.

scheduled and sitting in my car it passed by heard but not seen)

 

The Lamborghini Diablo is a high-performance mid-engined sports car that was built by Italian automaker Lamborghini between 1990 and 2001. It was the first Lamborghini capable of attaining a top speed in excess of 200 miles per hour (320 km/h). After the end of its production run in 2001, the Diablo was replaced by the Lamborghini Murciélago. Diablo is "devil" in Spanish, which is diavolo in Italian.

 

History of development

 

At a time when the company was financed by the Swiss-based Mimran brothers, Lamborghini began development of what was codenamed Project 132 in June 1985 as a replacement for the Countach model. The brief stated that its top speed had to be at least 315 km/h (196 mph).

 

The design of the car was contracted to Marcello Gandini, who had designed its two predecessors. When Chrysler bought the company in 1987, providing money to complete its development, its management was uncomfortable with Gandini’s designs and commissioned its design team in Detroit to execute a third extensive redesign, smoothing out the trademark sharp edges and corners of Gandini's original design, and leaving him famously unimpressed. In fact, Gandini was so disappointed with the "softened" shape that he would later realize his original design in the Cizeta-Moroder V16T.

 

The car became known as the Diablo, carrying on Lamborghini's tradition of naming its cars after breeds of fighting bull. The Diablo was named after a ferocious bull raised by the Duke of Veragua in the 19th century, famous for fighting an epic battle with 'El Chicorro' in Madrid on July 11, 1869. In the words of Top Gear presenter Jeremy Clarkson, the Diablo was designed "solely to be the biggest head-turner in the world."

 

The development is believed to have cost a total of 6 billion Italian lira.

 

Diablo VT Roadster

 

1995-1998 Lamborghini Diablo VT Roadster

 

The Diablo VT Roadster was introduced in December 1995 and featured an electrically operated carbon fiber targa top which was stored above the engine lid when not in use. Besides the roof, the roadster's body was altered from the fixed-top VT model in a number of ways. The front bumper was revised, replacing the quad rectangular driving lamps with two rectangular and two round units. The brake cooling ducts were moved inboard of the driving lamps and changed to a straked design, while the rear ducts featured the vertical painted design seen on the SE30.

 

The engine lid was changed substantially in order to vent properly when the roof panel was covering it. The roadster also featured revised 17 inch wheels. The air intakes on top/sides were made larger than the coupe Diablos. In 1998 the wheels have been updated to 18 inch, and the engine power raised to 530 HP by adding the variable valve timing system. Top speed specification was raised to 335 km/h (208 mph).

 

In 1999 the dashboard received a major optical update by Audi, and the pop-up headlights were replaced by fixed headlights, same as for the coupés. This resulted in a better aerodynamic shape and modern optics.

 

[Text from Wikipedia]

 

en.wikipedia.org/wiki/Lamborghini_Diablo

 

This Lego miniland scale Lamborghini Diablo VT Roadster has been created for Flickr LUGNuts' 96th Build Challenge - The 8th Birthday, titled - 'Happy Crazy Eight Birthday, LUGNuts' - where all previous build challenges are available to build to. This model is built to the LUGNuts 92nd build challenge, - "Stuck in the 90s" featuring vehicles from the decade of the 1990s

In the capable hands of one of Metroline's compliment of lady drivers, RML 2471 is seen at Aldwych on the start of its busy journey through the West End and up the Edgware Road on route 6 to Willesden Garage early one afternoon in June 2002. This post-London Buses version of Metroline livery applied to their Routemaster fleets based at Willesden (AC) and Holloway (HT) bus garages was an attractive combination with a shallow dark blue skirt and blue grille mesh whilst still retaining the white relief band.

Some background:

The VF-1 was developed by Stonewell/Bellcom/Shinnakasu for the U.N. Spacy by using alien Overtechnology obtained from the SDF-1 Macross alien spaceship. The space-capable VF-1's combat debut was on February 7, 2009, during the Battle of South Ataria Island - the first battle of Space War I - and remained the mainstay fighter of the U.N. Spacy for the entire conflict. Introduced in 2008, the VF-1 would be out of frontline service just five years later, though.

 

The VF-1 proved to be an extremely capable craft, successfully combating a variety of Zentraedi mecha even in most sorties which saw UN Spacy forces significantly outnumbered. The versatility of the Valkyrie design enabled the variable fighter to act as both large-scale infantry and as air/space superiority fighter. The basic VF-1 was built and deployed in four minor variants (designated A, J, and S single-seater and the D two-seater/trainer) and its success was increased by continued development of various enhancements including the GBP-1S "Armored" Valkyrie exoskeleton with enhanced protection and integrated missile launchers, the so-called FAST (“Fuel And Sensor Tray”) packs that created the fully space-capable "Super" Valkyries and the additional RÖ-X2 heavy cannon pack weapon system for the VF-1S “Super Valkyrie”.

 

After the end of Space War I, the VF-1 continued to be manufactured both in the Sol system and throughout the UNG space colonies. At the end of 2015 the final rollout of the VF-1 was celebrated at a special ceremony, commemorating this most famous of variable fighters. The VF-1 Valkryie was built from 2006 to 2013 with a total production of 5,459 VF-1 variable fighters with several original variants (VF-1A = 5,093, VF-1D = 85, VF-1J = 49, VF-1S = 30, VF-1G = 12, VE-1 = 122, VT-1 = 68), even though these machines were frequently updated and modified during their career, leading to a wide range of sub-variants and different standards.

 

Although the VF-1 would be replaced in 2020 as the primary Variable Fighter of the U.N. Spacy, a long service record and continued production after the war proved the lasting worth of the design. One of these post-war designs became the VF-1EX, a replica variant of the VF-1J with up-to-date avionics and instrumentation. It was only built in small numbers in the late 2040s and was a dedicated variant for advanced training with dissimilar mock aerial and ground fighting.

 

The only operator of this type was Xaos (sometimes spelled as Chaos), a private and independent military and civilian contractor. Xaos was originally a fold navigation business that began venturing into fold wave communication and information, expanding rapidly during the 2050s and entering new business fields like flight tests and providing aggressor aircraft for military training. They were almost entirely independent from the New United Nations Spacy (NUNS) and was led by the mysterious Lady M. During the Vár Syndrome outbreak, Echo Squadron and Delta Flight and the tactical sound unit Thrones and Walküre were formed to counteract its effects in the Brísingr Globular Cluster.

 

The VF-1EX was restricted to its primary objective and never saw real combat. The replica unit retained the overall basic performance of the original VF-1 Valkyrie, the specifications being more than sufficient for training and mock combat. The only difference was the addition of the contemporary military EG-01M/MP EX-Gear system for the pilot as an emergency standard, an exoskeleton unit with personal inner-wear, two variable geometry wings, two hybrid jet/rocket engines, mechanical hardware for the head, torso, arms and legs. This feature gave the VF-1EX its new designation.

Furthermore, the VF-1EX was also outfitted with other electronic contingency functions like AI-assisted flight and remote override controls. Some of these features could be disabled according to necessity or pilot preferences. The gun pod unit was retained but was usually only loaded with paintball rounds for mock combat. For the same purpose, one of the original Mauler RÖV-20 anti-aircraft laser cannon in the "head unit" was replaced by a long-range laser target designator. AMM-1 missiles with dummy warheads or other training ordnance could be added to the wing hardpoints, but the VF-1EX was never seen being equipped this way - it remained an agile dogfighter.

  

General characteristics:

All-environment variable fighter and tactical combat Battroid. 3-mode variable transformation; variable geometry wing; vertical take-off and landing; control-configurable vehicle; single-axis thrust vectoring; three "magic hand" manipulators for maintenance use; retractable canopy shield for Battroid mode and atmospheric reentry; EG-01M/MP EX-Gear system; option of GBP-1S system, atmospheric-escape booster, or FAST Pack system.

 

Accommodation:

Single pilot in Marty & Beck Mk-7 zero/zero ejection seat

 

Dimensions:

Battroid Mode:

Height 12.68 meters

Width 7.3 meters

Length 4.0 meters

Fighter Mode:

Length 14.23 meters

Wingspan 14.78 meters (at 20° minimum sweep)

Height 3.84 meters

 

Empty weight: 13.25 metric tons

Standard take-off mass: 18.5 metric tons

MTOW: 37.0 metric tons

 

Power Plant:

2x Shinnakasu Heavy Industry/P&W/Roice FF-2001 thermonuclear reaction turbine engines, output 650 MW each, rated at 11,500 kg in standard or in overboost (225.63 kN x 2);

4x Shinnakasu Heavy Industry NBS-1 high-thrust vernier thrusters (1 x counter reverse vernier thruster nozzle mounted on the side of each leg nacelle/air intake, 1 x wing thruster roll control system on each wingtip);

18x P&W LHP04 low-thrust vernier thrusters beneath multipurpose hook/handles

 

Performance:

Battroid Mode: maximum walking speed 160 km/h

Fighter Mode: at 10,000 m Mach 2.71; at 30,000+ m Mach 3.87

g limit: in space +7

Thrust-to-weight ratio: empty 3.47; standard TOW 2.49; maximum TOW 1.24

 

Transformation:

Standard time from Fighter to Battroid (automated): under 5 sec.

Min. time from Fighter to Battroid (manual): 0.9 sec.

 

Armament:

1x Mauler RÖV-20 anti-aircraft laser cannon in the "head" unit, firing 6,000 pulses per minute

1x Howard GU-11 55 mm three-barrel Gatling gun pod with 200 RPG, fired at 1,200 rpm

4x underwing hardpoints for a wide variety of ordnance

  

The kit and its assembly:

The VF-1EX Valkyrie is a Variable Fighter introduced in the Macross Δ television series, and it's, as described above, a replica training variant that resembles outwardly the VF-1J. There's even a Hasegawa 1:72 kit from 2016 of this obscure variant.

However, what I tried to recreate is a virtual (and purely fictional/non-canonical) VF-1EX, re-skinned by someone called David L. on the basis of a virtual VF-1S 3D model with a 2 m wing span (sounds like ~1:8 scale) for the Phoenix R/C simulator software. Check this for reference: www.supermotoxl.com/projects-articles/ready-to-drive-fly-...). How bizarre can things be/become? And how sick is a hardware model of it, though...?

 

I found the complex livery very attractive and had the plan to build a 1:100 model for some years now. But it took this long to gather enough mojo to tackle this project, due to the tricolor paint scheme's complex nature...

The "canvas" for this stunt is a vintage Arii 1:100 VF-1 kit, built OOB except for some standard mods. The kit was actually a VF-1A, but I had a spare VF-1J head unit in store as a suitable replacement. Externally, some dorsal blade aerials and vanes on the nose were added, the attachment points under the wings for the pylons were PSRed away. A pilot figure was added to the cockpit because this model would be displayed in flight. As a consequence, the ventral gun pod received an adapter at its tail and I added one of my home-brew wire displays, created on the basis of the kit's OOB plastic base.

  

Painting and markings:

As mentioned above, this VF-1 is based on a re-skinned virtual R/C model, and its creator apparently took inspiration from a canonical VF fighter, namely a VF-31C "Siegfried", and specifically the "Mirage Farina Jenius Custom" version from the Macross Δ series that plays around 2051. Screenshots from the demo flight video under the link above provided various perspectives as painting reference, but the actual implementation on the tiny model caused serious headaches.

The VF-1's shapes are rather round and curvy, the model's jagged surface and small size prohibited masking. The kit is IMHO also best built and painted in single sub-assemblies, but upon closer inspection the screenshots revealed some marking inconsistencies (apparently edited from various videos?), and certain areas were left uncertain, e .g. the inside of the legs or the whole belly area. Therefore, this model is just a personal interpretation of the design, and as such I also deviated in the markings.

 

The paints became Humbrol 20 (Crimson) and 58 (Magenta), plus Revell 301 (Semi-gloss White), and they were applied with brushes. To replicate the edgy and rather fragmented pattern I initially laid down the two reds in a rather rough and thin fashion and painted the white dorsal and ventral areas. Once thoroughly dry, the white edges were quasi-masked with white decal material, either with stripes of various widths or tailored from sheet material, e. g. for the "wedges" on the wings and fins and the dorsal "swallow tail". This went more smoothly than expected, with a very convincing and clean result that i'd never had achieved with brushes alone, even with masking attempts, which would probably have led to chaos and too much paint on the model.

 

Other details like the grey leading edges or the air intakes were created with grey and black decal material, too.

No weathering was done, since the aircraft would be clean and in pristine condition, but I used a soft pencil to emphasize the engraved panel lines, esp. on white background. The gun pod became grey and the exhausts, painted in Revell 91 (Iron), were treated with graphite for a darker shade and a more metallic look.

 

Stencils came from the kit's OOB sheet, but only a few, since there was already a lot "going on" on the VF-1's hull. The flash-shaped Xaos insignia and the NUNS markings on legs and wings were printed at home - as well as the small black vernier thrusters all around the hull, for a uniform look. The USN style Modex and the small letter code on the fins came from an Colorado Decals F-5 sheet, for an aggressor aircraft.

 

Finally, the kit was sealed overall with semi-gloss acrlyic varnish (which turned out glossier than expected...) and position lights etc. added with translucent paint on top of a silver base.

  

Well, while the VF-1 was built OOB with no major mods and just some cosmetical upgrades, the paint scheme and its finish were more demanding - and I am happy that the "decal masking" trick worked so fine. The paint scheme surely is attractive, even though it IMHO does not really takes the VF-1's lines into account. Nevertheless, I am certain that there are not many models that are actually based on a virtual 1:8 scale 3D model of an iconic SF fighter, so that this VF-1EX might be unique.

 

Toa Tamaru is capable of wielding a twin set of swords and shields that offers her a balanced defense and offense.

 

Nova beam swords that can launch plasma projectiles when swung with perfected skill

 

Ignore light weight armor & walls. penetrating through easily with her blades reaching a temperature of at least 1800°C, and could be high as 25000°C.

 

Her shields dont heat up the same as her swords but are required to cool down to recharge

Capable of carrying 2,000 passengers, 1,342 cars and 240 trucks, Irish Ferries MV Ulysses provides huge capacity on the Holyhead to Dublin route.

It is seen here passing The Skerries, (Ynysoedd y Moelrhoniaid).

A hoist-capable UH-60 Black Hawk helicopter and aircrew from the 1st Battalion, 207th Aviation Regiment, Alaska Army National Guard, arrives in Bethel, Alaska, April 27, 2021, as part of the State of Alaska’s effort to prepare for disaster response in the Yukon-Kuskokwim region during the spring flood season. While stationed in Bethel, the crew will continue to train on their federal mission and remain ready to respond to any requests for support from civil authorities through the State Emergency Operations Center. (U.S. Army National Guard photo by Dana Rosso)

Some background:

The VF-1 was developed by Stonewell/Bellcom/Shinnakasu for the U.N. Spacy by using alien Overtechnology obtained from the SDF-1 Macross alien spaceship. It was preceded into production by an aerodynamic proving version of its airframe, the VF-X. Unlike all later VF vehicles, the VF-X was strictly a jet aircraft, built to demonstrate that a jet fighter with the features necessary to convert to Battroid mode was aerodynamically feasible.

 

After the VF-X's testing was finished, an advanced concept atmospheric-only prototype, the VF-0 Phoenix, was flight-tested from 2005 to 2007 and briefly served as an active-duty fighter from 2007 to the VF-1's rollout in late 2008, while the bugs were being worked out of the full-up VF-1 prototype (VF-X-1).

 

The space-capable VF-1's combat debut was on February 7, 2009, during the Battle of South Ataria Island - the first battle of Space War I, and was the mainstay fighter of the U.N. Spacy for the entire conflict. Introduced in 2008, the VF-1 would be out of frontline service just five years later.

 

The VF-1 proved to be an extremely capable craft, successfully combating a variety of Zentraedi mecha even in most sorties, which saw UN Spacy forces significantly outnumbered. The versatility of the Valkyrie design enabled the variable fighter to act as both large-scale infantry and as air/space superiority fighter. The signature skills of U.N. Spacy ace pilot Maximilian Jenius exemplified the effectiveness of the variable systems as he near-constantly transformed the Valkyrie in battle to seize advantages of each mode as combat conditions changed from moment to moment.

 

The basic VF-1 was deployed in four minor variants (designated A, D, J, and S) with constant updates and several sub-variants during its long and successful career. Its success was increased by the GBP-1S "Armored" Valkyrie and FAST Pack "Super" Valkyrie weapon systems, the latter enabling the fighter to operate in space.

 

After the end of Space War I, the VF-1 continued to be manufactured both in the Sol system (notably on the Lunar facility Apollo Base) and throughout the UNG space colonies. Although the VF-1 would eventually be replaced as the primary VF of the UN Spacy by the more capable, but also much bigger, VF-4 Lightning III in 2020, a long service record and continued production after the war proved the lasting worth of the design.

 

The VF-1 was without doubt the most recognizable variable fighter of Space War I and was seen as a vibrant symbol of the U.N. Spacy even into the first year of the New Era 0001 in 2013. At the end of 2015 the final rollout of the VF-1 was celebrated at a special ceremony, commemorating this most famous of variable fighters.

 

The 1st generation VF-1 Valkryie was built from 2006 to 2013 with a total production of 5,459 VF-1 variable fighters and in several variants (VF-1A = 5,093, VF-1D = 85, VF-1J = 49, VF-1S = 30, VF-1G = 12, VE-1 = 122, VT-1 = 68). However, the type proved to be very versatile and many more VF-1s were built from spares, and ongoing modernization programs like the “Plus” MLU update incorporated stronger engines and avionics from the VF-1’s successor, the VF-4 (including the more powerful radar, IRST sensor and a laser designator/range finder). These updates later led to the VF-1N, P and X variants, which, among modernized avionics and an improved cockpit layout, featured modified wings.

 

However, the fighter remained active in many second line units and continued to show its worthiness years later, e. g. through Milia Jenius who would use her old VF-1 fighter in defense of the colonization fleet - 35 years after the type's service introduction!

  

General characteristics:

Equipment Type: all-environment variable fighter and tactical combat battroid

Government: U.N. Spacy, U.N. Navy, U.N. Space Air Force

Accommodation: pilot only in Marty & Beck Mk-7 zero/zero ejection seat

Dimensions:

Fighter Mode:

- Length 14.23 meters

- Wingspan 14.78 meters (fully extended)

- Height 3.84 meters

Battroid Mode:

- Height 12.68 meters

- Width 7.3 meters

- Length 4.0 meters

Empty weight: 13.25 metric tons

Standard T-O mass: 18.5 metric tons

MTOW: 37.0 metric tons

 

Powerplant:

2x Shinnakasu Heavy Industry/P&W/Roice FF-2008 thermonuclear reaction turbine engines,

output 650 MW each, rated at 11,500 kg in standard or in overboost (225.63 kN x 2)

4x Shinnakasu Heavy Industry NBS-1 high-thrust vernier thrusters (1 x counter reverse

vernier thruster nozzle mounted on the side of each leg nacelle/air intake,

1x wing thruster roll control system on each wingtip)

18x P&W LHP04 low-thrust vernier thrusters beneath multipurpose hook/handles

 

Performance:

Battroid Mode: maximum walking speed 160 km/h

Fighter Mode: at 10,000 m Mach 2.71; at 30,000+ m Mach 3.87

g limit: in space +7

Thrust-to-weight ratio: empty 3.47; standard T-O 2.49; maximum T-O 1.24

 

Design features:

3-mode variable transformation; variable geometry wing; vertical take-off and landing; control-configurable vehicle; single-axis thrust vectoring; three "magic hand" manipulators for maintenance use; retractable canopy shield for Battroid mode and atmospheric reentry; option of GBP-1S system, atmospheric-escape booster, or FAST Pack system

 

Transformation:

Standard time from Fighter to Battroid (automated): under 5 sec.

Minimum time from Fighter to Battroid (manual): 0.9 sec.

 

Armament:

1x internal Mauler RÖV-20 anti-aircraft laser cannon, firing 6,000 pulses per minute

1x Howard GU-11 55 mm three-barrel Gatling gun pod with 200 rds fired at 1,200 rds/min

4x underwing hard points for a wide variety of ordnance, including

- 12x AMM-1 hybrid guided multipurpose missiles (3/point), or

- 12x MK-82 LDGB conventional bombs (3/point), or

- 6x RMS-1 large anti-ship reaction missiles (2/outboard point, 1/inboard point), or

- 4x UUM-7 micro-missile pods (1/point), each carrying 15x Bifors HMM-01 micro-missiles,

or a combination of above load-outs

 

Optional Armament:

Shinnakasu Heavy Industry GBP-1S ground-combat protector weapon system, or

Shinnakasu Heavy Industry FAST Pack augmentative space weapon system

 

The kit and its assembly:

Another submission to the 2017 "Science Fiction" Group Build at whatifmodelers.com, and once more the eventual realization of a long- plan: a VF-1 in a dazzle scheme! To my surprise, I have never seen this, neither in the canonical sources (except for a VF-5000 with an all-grey splinter scheme, similar to the experimental US Keith Ferris schemes), nor on a model? Well, time to try this stunt ...again; I had actually built a VF-1D as a non-transformable supersonic trainer many years ago, and applied a livery inspired by the Keith Ferris schemes, but with very soft blue-grey tones, so that the disruptive effect of the underlying splinter would hardly "work". So, this is a second approach to the theme, and a more visually-oriented one.

 

This vintage ARII VF-1J fighter kit was built OOB, with the landing gear tucked up. This kit showed its age, though, the moulds seem to be well worn because the sprues showed considerable flash and other soft spots.

Anyway, the model received my usual additions of some blade antennae, a pilot figure and a custom display stand in/under the ventral cannon pod. The ordnance is standard, too, the full load of a dozen AAM-1 missiles is OOB. The only true additions are a small, scratched fairing for an IRST sensor under the nose, seen in a source book profile of an U.N.S.A.F. VF-1, and RHAWS antennae at the top of the fins.

  

Painting and markings:

This was the bigger part of the work, and a creative one, too. I did not simply want to copy an existing scheme, e .g. the Keith Ferris schemes that had been tested on some US aircraft.

 

The scheme was to be disruptive, confusing and also decorative - true camouflage was rather a secondary requirement, but welcome. Creating such a scheme from scratch is not as easy as it sounds, because you have to avoid collisions of the same color, the overall look needs some balance, and the scheme and its single shard shapes were to somewhat correspond with the Valkyrie’s outlines, too.

Since I did not dare to improvise this directly on the kit, and because I wanted to use more than three tones for the paint scheme, I actually created a VF-1 4-side view on a sheet of paper and started painting it out with colored pencils!

 

This was actually very helpful and I ended up with a four-tone scheme, rooted in pure black and white and somewhat inspired by pre-WWII dazzle schemes for ships.

Consequently the tones are black (I used a tone called Tar Black, Revell 6, which is actually a very dark grey), a dark/medium grey (Humbrol 27), light grey (Humbrol 64) and white (again, not the pure tone, but rather a very light grey, mixed from 95% Humbrol 130 and 5% Humbrol 64).

 

The pattern consists of large color sections, geometrical shapes, wedges and a few stripes at some intersections. It (unintentionally) reminds of certain late Su-27 schemes in Russian services, as well as US aggressors that carry similar outfits, e. g. some F-18s of USN’s VFC-12. But these are rather geometrical shapes added to a camouflage/grey background, and not as integral as my design.

 

The scheme was applied mostly free-handedly with brushes and a mix of enamels and acrylic paint. From certain angles it actually breaks up the VF-1's outlines well, esp. its silhouette, and at a quick glance it is actually hard to tell the Valkyrie’s orientation or direction of flight. In order to add some more onlooker confusion, I also added a fake cockpit with a white pilot helmet (cut from decal sheet) on top of the fuselage.

 

All other markings are rather minimal and subdued. Lacking different contrasting color options, I used yellow decals for the “U.N. Spacy” tags on the legs and the upper starboard wing. The “kite” insignia in grey and white were printed at home, while the tactical code comes from a Tamiya 1:100 Thunderchief. The chequered stripe on top of the fin is a generic decal, and blank, beige decal sheet was used for the wings’ and fins’ leading edges.

The rest came mostly from various OOB VF-1 sheets.

 

The ordnance was painted authentically, too. The AMM-1’s became all-white with black and red trim, the gun pod was painted Dark Sea Grey (Humbrol 123), blending into the overall color palette of this dazzle VF-1.

 

Except for a black ink wash, emphasizing the engraved panel lines, not much other weathering was done. Finally, the kit was sealed with matt acrylic varnish.

  

An… interesting result, and I am surprised how much the dazzle scheme changes the overall look of the VF-1, despite no fundamental changes to the airframe as such. Building was relatively simple, but the kit is not complex – just pretty old. Anyway, this updated aggressor bird makes a nice addition to the VF-1 collection, a worthwhile effort. A true eye catcher, I’d say.

HI Fiona,

It was a great event! Please see below the story and some photos attached, if you'd like to post this on Indigo where appropriate and on the gallery, I will leave this into your capable hands!

Thanks again for the contribution. We really had a good and inspiring time!

Sandrine

 

****

 

Encouraged by Informa`s One Planet Eating initiatives, the Hong Kong team got together at HOME to share a few healthy tapas, organic cocktails and be inspired by Christian Mongendre, our Guest Speaker, who created HOME. You can check him out: www.lifestyleasia.com/470121/tastemakers-christian-mongen...

 

In balancing mind and body, HOME - Eat to Live strives to use only organic produce whenever possible. Much of our ingredients are sourced locally from a network of farms and our food is made fresh daily. Our menu aims to appeal to everyone. We believe that healthy, plant-based foods should be tasty, filling, and nutritious. We offer vegan, gluten free & raw options, including healthy desserts and organic cocktails. We are committed to supporting a sustainable, plant-based lifestyle, collectively lowering our carbon footprint and preserving our earth's fresh water supply through a plant-based menu, mindful ingredient sourcing, eco-friendly packaging and practices.

 

During the talk, Christian raised awareness about recycling, compost, biodegradable materials like the plastic they use, from corn, LED lights which create no heat.

 

He also told us about the importance of eating more plant based food, and the impact on our planet. As a very demanding person, he wanted to create a vegetarian and sustainable restaurant and also bring taste and colour to our plates, with no processed food. Christian also pointed out the menu of HOME, each dish is called by animals in danger: Golden Snub Nosed Monkey Open Faced Toast, Manta Ray Salad Bowl, Siberian Tiger Earth Bowl, Northern White Rhino Sliders , Hawaiian Monk Seal Flatbread...

 

The team was very engaged and questioned him around the cost of eating healthy, being higher than eating meat. At HOME, they try to educate their customers about the origin of the products they use, Kale is one example, they were the first restaurant to import Kale but as demand grows, price goes down and we reach economies of scale. To make 'Healthy food' affordable, the market demand need to change and it is starting to change.

 

Finally, we asked him for advice around Pledges we should all make:

 

- Wellbeing = Food, "you are what you eat" , what you are eating to regenerate your body

 

- How are you breathing: Try to take time and be conscious of your breath

 

- Try Meditation

 

- Drink high quality water and not distilled

 

- Exercise and organise more events like 'Walk the World'

 

- Cut down on sweets and opt for healthier snacks

 

- Choose an organic range of teas

 

- Recycle

 

- Having LED lights

 

- And last but not least, we all agreed to at least TRY: Meat Free Monday !

 

Alena & Sandrine

 

Sandrine Declippeleir

Account Director - Professional Services, Asia Pacific

 

Business intelligence | informa

 

T: +852 3757 9703

M: +852 9222 1747

sandrine.declippeleir@informa.com<

 

www.informa.com

Agribusiness intelligence | Financial intelligence | Maritime intelligence | Pharma intelligence | TMT intelligence

 

Informa | Nexxus Building, Level 16 | 41 Connaught Road | Central | Hong Kong

 

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The Lamborghini Diablo was a high-performance mid-engined sports car built by Italian automaker Lamborghini between 1990 and 2001. It was the first Lamborghini capable of attaining a top speed in excess of 200 miles per hour (320 km/h). After the end of its production run in 2001, the Diablo was replaced by the Lamborghini Murciélago.

 

The car became known as the Diablo, carrying on Lamborghini's tradition of naming its cars after breeds of fighting bull. The Diablo was named after a ferocious bull raised by the Duke of Veragua in the 19th century, famous for fighting an epic battle with 'El Chicorro' in Madrid on July 11, 1869.

 

After Audi AG took over Lamborghini from its former South East Asian owners in 1998, Mycom and VPower, they set out to modernize and refine the Diablo, while its replacement, the Murciélago, was developed. Audi tasked Luc Donckerwolcke with designing a more refined, more civilized, and more modern Diablo. The 6.0 VT was the result of that design. It featured heavy styling changes both inside and out; the front bumper now featured two large air intakes and the nose was flattened. It sat on large 18 inch monoblock alloy wheels reminiscent of the five hole dial wheels of the Countach. Significant changes were made to the interior too, the drivers seat was moved in line with the pedals, and climate control air conditioning was standard. There was a much larger use of carbon fibre too, to the point that only the doors and roof were metal. (alloy and steel respectively) Magnesium was used for the wheels, cylinder heads and inlet manifolds, and the con-rods were made from titanium. The centre console was one large piece of carbon fiber.

 

The 6.0 VT featured the new 6.0 litre V12, based on the motor that powered the Diablo GT (which in itself was essentially a modified version of the 5.7) The motor had updated ECU software in addition to new intake and exhaust systems and a refined variable valve timing system with slightly less aggressive camshafts than had been used in the earlier versions. With a power output of 550 BHP directly from the factory, the Diablo VT 6.0 was again to be considered a major competitor in the super car league, and Automobili Lamborghini SpA focused all their resources on this final Diablo model and the successor, all other models in the range were halted, no more Roadster or SV models were offered. The 6.0 VT had higher comfort levels, came with air conditioning as standard, the seats were much improved and the interior draped in glistening carbon fibre. The build quality was superior to any previous Diablo model. These improvements would make the 6.0 VT the most practical of all the Diablos.

Mercedes-Benz World

 

A facility at the historic Brooklands motor racing circuit owned and operated by Mercedes-Benz.

 

Home to the largest display of Mercedes-Benz cars in the UK, Mercedes-Benz World is so much more than just a retail site.

 

The facilities include:

 

Mercedes-Benz Museum

Handling Circuit

Off-Road Circuit

Skid Pan

Café

Restaurant

Mercedes-Benz Store

Silver Arrows Display Team

Mercedes-Benz Premier Dealership

  

www2.mercedes-benz.co.uk/content/unitedkingdom/mpc/mpc_un...

 

www.mercedes-benzretailgroup.co.uk/mercedes-benz-cars/abo...

 

Mercedes-AMG G 63 4MATIC Colour Edition

 

Available in five new exterior paints: Tomato Red, Alien Green, Galactic Green, Solar Beam and Sunset Beam,

 

The off-road capabilities of the G-Class have assumed near legendary status amongst 4x4 aficionados. The permanent four-wheel drive, the 4ETS Four-wheel Electronic Traction System, the synchronised transfer case and the three 100% differential locks, all work together in perfect harmony to make the G-Class a match for the toughest terrain.

 

Fitted as standard, the innovative transfer case’s off-road ratio is a key component. Activated at the touch of a switch, it generates formidable traction, enabling a stunning gradient-climbing capability of up to 80%.

 

Similarly, the differential locks can be activated individually and in a logically specified sequence – so you can adapt the vehicle perfectly to its surroundings. If a wheel loses traction, the power is redirected to the wheels offering the best grip. Even if only one wheel is providing grip, you will still make good headway.

 

Not cheap at £150,635.00 but it is supposed to be the world's most capable off roader. I won't be getting one of these.

 

It seems unbelievable that a company capable of making something like this is also capable of producing the masses of nasty generics littering U.K. retailers! HTI have a long history of importing other peoples 1/64 castings but a few years ago they brought out a nice selection of licensed models based on modern BMW and Mercedes-Benz vehicles which showed a lot of promise. They also imported unlicensed but realistic castings from an unknown Chinese manufacturer but now pretty much all of these have been swept aside by the inexorable rise of their deliberately generic offerings which our retailers have lapped up but not the buying public it seems!

This unlicensed Land-Rover Defender 110 is stuck somewhere in-between. It appears to be a HTI original yet has never been available as a single and invariably appears in farm based multi-sets. If they have the skills to make something like this so realistic and dare I say accurate why on earth can't they do the same to their other 1/64 products!

HTI do indeed make a Land-Rover approved Defender in 1/43 scale so heaven knows how they got away with producing a smaller scale version which isn't. It does without front and rear detailing but more than makes up for it in its robust construction, well proportioned body and an accurate facelifted dashboard design. Im certain selling this as a single and in a variety of Emergency liveries would create a lot of interest from collectors.

In loose but virtually mint condition on account of it being a recent charity shop gift.

The opening of the Connaught Bridge Generating Station, on the Klang River in Selangor, in March 1953 was a real milestone int he history of what was then Malaya - now Malaysia. The power station, capable of being either coal or oil fired, was at 80,000kw by far the largest generating station at the time in the country and, as importantly, the project included elements of a new proposed Malayan 'National Grid' that linked existing stations such as the hydro-electric plant at Chenderoh with stations and locations along the East Coast centred on the Bungsar station in Kuala Lumpur that hitherto had supplied the bulk of the capital's power requirements. As the booklet notes it meant an end to the long post-war years of restriction of supply to both industrial and domestic consumers.

 

The station was originally planned in 1944 by the Malayan Planning Unit in London in anticipation of the return to Malaya after the end of the Japanses occupation. A provisional order for the equipment was placed in 1945, with additional equipment following in 1947. Meanwhile the site at Connaught Bridge alongside the Klang River was selected in 1946 with the contract to start construction given by the Federation's Government in 1949. The first phase of the station, plant and the double circuit 66kv interconnecting lines running the 23 miles to Kuala Lumpur, was ready for opening in March 1953. Full commissioning came in 1955. Initailly the output was linked to the Bangsar (KL) station and that of Ulu Langat hydro-electric station. Construction of the former had started in 1926 and was opened in 1927 by the Government electricity department and in 1933 they purchased the Ulu Langat station from the Sungei Besi Mines Ltd. KL's earlier supplies, from 1905, had been provided from a small hydro-electric plant on the Gombak River, 12 miles from the town, what had two 400kw Pelton wheel-alternators. This had been augmented in 1919 by a mixed steam and diesel engine plant at Gombak Lane in the centre of KL.

 

Elsewhere, Penang's Municipal Department was the first to supply electriicty within Malaya when it started in 1904 - the station on the mainland at Prai came into use in 1926. By this date electricity was available in Ipoh, Johore Bahru (and Singapore), Seremban and Malacca/Melaka. That at Johore Bahru under the Johore adminsitraion grew to include Muar, Batu Pahat, Kluang, Kota Tinggi and Segamat. In Perak supplies were largely in the hands of the Perak River Hydro-Electric Power Company who operated stations at Malim Nawar (1928) and Chenderoh (1929). In North Perak the Government supplied Taiping and in Province Wellesley Messrs. Huttenbach's bought bulk supply from Penang and supplied power to various towns, supplemented by diesel generating stations in Kedah, Perak and Negri Sembilan. Power came to Kota Bharu (Kelantan), Ruab, Bentong, Kuala Lipis and Kuantan between 1928 and 1931, and in 1938 and 1939 to Mentakab, Fraser's Hill and Kuala Kubu.

 

In 1946 the Malayan Union Government acquired most electriicty undertakings except those of private companies and Penang Corporation whilst it also fully acquired the undertkaing operated by the Malacca Electric Light Company in 1948 that it has previously run on a rental basis. On the 1 September 1949 the new Central Electricity Board of the Federation fo Malaya came into existance and took over all functions of the old Electricity Department.

 

The booklet is marvellously detailed and illustrated describing the site, the power station, ancilliary equipment and other works, such as staff accomodaton and housing, with photographs and plans. The latter include a map of the proposed Malayan Grid and the plans show the works designed by both the staff of the Central Electricity Board and the consulting engineers, Preece, Cardew and Rider, and civil engineers Coode and Partners. The station took cooling water from the Klang River and could be powered by either fuel oil (via a pipeline from Port Swettenham) and coal via connections with the Malayan Railways and the colliery at Batu Arang.

 

Needless to say much of the equipment was supplied from the UK - Parsons generators and transformers and switchgear from various manufacturers including British Thomson Houston.

 

The photos are great as they show named members of the operating staff at work which is unusual but that now provided a real social history to the economic history of electricity supply in Malaysia.

See more photos of this, and the Wikipedia article.

 

Details, quoting from Smithsonian National Air and Space Museum | Lockheed SR-71 Blackbird:

 

No reconnaissance aircraft in history has operated globally in more hostile airspace or with such complete impunity than the SR-71, the world's fastest jet-propelled aircraft. The Blackbird's performance and operational achievements placed it at the pinnacle of aviation technology developments during the Cold War.

 

This Blackbird accrued about 2,800 hours of flight time during 24 years of active service with the U.S. Air Force. On its last flight, March 6, 1990, Lt. Col. Ed Yielding and Lt. Col. Joseph Vida set a speed record by flying from Los Angeles to Washington, D.C., in 1 hour, 4 minutes, and 20 seconds, averaging 3,418 kilometers (2,124 miles) per hour. At the flight's conclusion, they landed at Washington-Dulles International Airport and turned the airplane over to the Smithsonian.

 

Transferred from the United States Air Force.

 

Manufacturer:

Lockheed Aircraft Corporation

 

Designer:

Clarence L. "Kelly" Johnson

 

Date:

1964

 

Country of Origin:

United States of America

 

Dimensions:

Overall: 18ft 5 15/16in. x 55ft 7in. x 107ft 5in., 169998.5lb. (5.638m x 16.942m x 32.741m, 77110.8kg)

Other: 18ft 5 15/16in. x 107ft 5in. x 55ft 7in. (5.638m x 32.741m x 16.942m)

 

Materials:

Titanium

 

Physical Description:

Twin-engine, two-seat, supersonic strategic reconnaissance aircraft; airframe constructed largley of titanium and its alloys; vertical tail fins are constructed of a composite (laminated plastic-type material) to reduce radar cross-section; Pratt and Whitney J58 (JT11D-20B) turbojet engines feature large inlet shock cones.

 

Long Description:

No reconnaissance aircraft in history has operated in more hostile airspace or with such complete impunity than the SR-71 Blackbird. It is the fastest aircraft propelled by air-breathing engines. The Blackbird's performance and operational achievements placed it at the pinnacle of aviation technology developments during the Cold War. The airplane was conceived when tensions with communist Eastern Europe reached levels approaching a full-blown crisis in the mid-1950s. U.S. military commanders desperately needed accurate assessments of Soviet worldwide military deployments, particularly near the Iron Curtain. Lockheed Aircraft Corporation's subsonic U-2 (see NASM collection) reconnaissance aircraft was an able platform but the U. S. Air Force recognized that this relatively slow aircraft was already vulnerable to Soviet interceptors. They also understood that the rapid development of surface-to-air missile systems could put U-2 pilots at grave risk. The danger proved reality when a U-2 was shot down by a surface to air missile over the Soviet Union in 1960.

 

Lockheed's first proposal for a new high speed, high altitude, reconnaissance aircraft, to be capable of avoiding interceptors and missiles, centered on a design propelled by liquid hydrogen. This proved to be impracticable because of considerable fuel consumption. Lockheed then reconfigured the design for conventional fuels. This was feasible and the Central Intelligence Agency (CIA), already flying the Lockheed U-2, issued a production contract for an aircraft designated the A-12. Lockheed's clandestine 'Skunk Works' division (headed by the gifted design engineer Clarence L. "Kelly" Johnson) designed the A-12 to cruise at Mach 3.2 and fly well above 18,288 m (60,000 feet). To meet these challenging requirements, Lockheed engineers overcame many daunting technical challenges. Flying more than three times the speed of sound generates 316° C (600° F) temperatures on external aircraft surfaces, which are enough to melt conventional aluminum airframes. The design team chose to make the jet's external skin of titanium alloy to which shielded the internal aluminum airframe. Two conventional, but very powerful, afterburning turbine engines propelled this remarkable aircraft. These power plants had to operate across a huge speed envelope in flight, from a takeoff speed of 334 kph (207 mph) to more than 3,540 kph (2,200 mph). To prevent supersonic shock waves from moving inside the engine intake causing flameouts, Johnson's team had to design a complex air intake and bypass system for the engines.

 

Skunk Works engineers also optimized the A-12 cross-section design to exhibit a low radar profile. Lockheed hoped to achieve this by carefully shaping the airframe to reflect as little transmitted radar energy (radio waves) as possible, and by application of special paint designed to absorb, rather than reflect, those waves. This treatment became one of the first applications of stealth technology, but it never completely met the design goals.

 

Test pilot Lou Schalk flew the single-seat A-12 on April 24, 1962, after he became airborne accidentally during high-speed taxi trials. The airplane showed great promise but it needed considerable technical refinement before the CIA could fly the first operational sortie on May 31, 1967 - a surveillance flight over North Vietnam. A-12s, flown by CIA pilots, operated as part of the Air Force's 1129th Special Activities Squadron under the "Oxcart" program. While Lockheed continued to refine the A-12, the U. S. Air Force ordered an interceptor version of the aircraft designated the YF-12A. The Skunk Works, however, proposed a "specific mission" version configured to conduct post-nuclear strike reconnaissance. This system evolved into the USAF's familiar SR-71.

 

Lockheed built fifteen A-12s, including a special two-seat trainer version. Two A-12s were modified to carry a special reconnaissance drone, designated D-21. The modified A-12s were redesignated M-21s. These were designed to take off with the D-21 drone, powered by a Marquart ramjet engine mounted on a pylon between the rudders. The M-21 then hauled the drone aloft and launched it at speeds high enough to ignite the drone's ramjet motor. Lockheed also built three YF-12As but this type never went into production. Two of the YF-12As crashed during testing. Only one survives and is on display at the USAF Museum in Dayton, Ohio. The aft section of one of the "written off" YF-12As which was later used along with an SR-71A static test airframe to manufacture the sole SR-71C trainer. One SR-71 was lent to NASA and designated YF-12C. Including the SR-71C and two SR-71B pilot trainers, Lockheed constructed thirty-two Blackbirds. The first SR-71 flew on December 22, 1964. Because of extreme operational costs, military strategists decided that the more capable USAF SR-71s should replace the CIA's A-12s. These were retired in 1968 after only one year of operational missions, mostly over southeast Asia. The Air Force's 1st Strategic Reconnaissance Squadron (part of the 9th Strategic Reconnaissance Wing) took over the missions, flying the SR-71 beginning in the spring of 1968.

 

After the Air Force began to operate the SR-71, it acquired the official name Blackbird-- for the special black paint that covered the airplane. This paint was formulated to absorb radar signals, to radiate some of the tremendous airframe heat generated by air friction, and to camouflage the aircraft against the dark sky at high altitudes.

 

Experience gained from the A-12 program convinced the Air Force that flying the SR-71 safely required two crew members, a pilot and a Reconnaissance Systems Officer (RSO). The RSO operated with the wide array of monitoring and defensive systems installed on the airplane. This equipment included a sophisticated Electronic Counter Measures (ECM) system that could jam most acquisition and targeting radar. In addition to an array of advanced, high-resolution cameras, the aircraft could also carry equipment designed to record the strength, frequency, and wavelength of signals emitted by communications and sensor devices such as radar. The SR-71 was designed to fly deep into hostile territory, avoiding interception with its tremendous speed and high altitude. It could operate safely at a maximum speed of Mach 3.3 at an altitude more than sixteen miles, or 25,908 m (85,000 ft), above the earth. The crew had to wear pressure suits similar to those worn by astronauts. These suits were required to protect the crew in the event of sudden cabin pressure loss while at operating altitudes.

 

To climb and cruise at supersonic speeds, the Blackbird's Pratt & Whitney J-58 engines were designed to operate continuously in afterburner. While this would appear to dictate high fuel flows, the Blackbird actually achieved its best "gas mileage," in terms of air nautical miles per pound of fuel burned, during the Mach 3+ cruise. A typical Blackbird reconnaissance flight might require several aerial refueling operations from an airborne tanker. Each time the SR-71 refueled, the crew had to descend to the tanker's altitude, usually about 6,000 m to 9,000 m (20,000 to 30,000 ft), and slow the airplane to subsonic speeds. As velocity decreased, so did frictional heat. This cooling effect caused the aircraft's skin panels to shrink considerably, and those covering the fuel tanks contracted so much that fuel leaked, forming a distinctive vapor trail as the tanker topped off the Blackbird. As soon as the tanks were filled, the jet's crew disconnected from the tanker, relit the afterburners, and again climbed to high altitude.

 

Air Force pilots flew the SR-71 from Kadena AB, Japan, throughout its operational career but other bases hosted Blackbird operations, too. The 9th SRW occasionally deployed from Beale AFB, California, to other locations to carryout operational missions. Cuban missions were flown directly from Beale. The SR-71 did not begin to operate in Europe until 1974, and then only temporarily. In 1982, when the U.S. Air Force based two aircraft at Royal Air Force Base Mildenhall to fly monitoring mission in Eastern Europe.

 

When the SR-71 became operational, orbiting reconnaissance satellites had already replaced manned aircraft to gather intelligence from sites deep within Soviet territory. Satellites could not cover every geopolitical hotspot so the Blackbird remained a vital tool for global intelligence gathering. On many occasions, pilots and RSOs flying the SR-71 provided information that proved vital in formulating successful U. S. foreign policy. Blackbird crews provided important intelligence about the 1973 Yom Kippur War, the Israeli invasion of Lebanon and its aftermath, and pre- and post-strike imagery of the 1986 raid conducted by American air forces on Libya. In 1987, Kadena-based SR-71 crews flew a number of missions over the Persian Gulf, revealing Iranian Silkworm missile batteries that threatened commercial shipping and American escort vessels.

 

As the performance of space-based surveillance systems grew, along with the effectiveness of ground-based air defense networks, the Air Force started to lose enthusiasm for the expensive program and the 9th SRW ceased SR-71 operations in January 1990. Despite protests by military leaders, Congress revived the program in 1995. Continued wrangling over operating budgets, however, soon led to final termination. The National Aeronautics and Space Administration retained two SR-71As and the one SR-71B for high-speed research projects and flew these airplanes until 1999.

 

On March 6, 1990, the service career of one Lockheed SR-71A Blackbird ended with a record-setting flight. This special airplane bore Air Force serial number 64-17972. Lt. Col. Ed Yeilding and his RSO, Lieutenant Colonel Joseph Vida, flew this aircraft from Los Angeles to Washington D.C. in 1 hour, 4 minutes, and 20 seconds, averaging a speed of 3,418 kph (2,124 mph). At the conclusion of the flight, '972 landed at Dulles International Airport and taxied into the custody of the Smithsonian's National Air and Space Museum. At that time, Lt. Col. Vida had logged 1,392.7 hours of flight time in Blackbirds, more than that of any other crewman.

 

This particular SR-71 was also flown by Tom Alison, a former National Air and Space Museum's Chief of Collections Management. Flying with Detachment 1 at Kadena Air Force Base, Okinawa, Alison logged more than a dozen '972 operational sorties. The aircraft spent twenty-four years in active Air Force service and accrued a total of 2,801.1 hours of flight time.

 

Wingspan: 55'7"

Length: 107'5"

Height: 18'6"

Weight: 170,000 Lbs

 

Reference and Further Reading:

 

Crickmore, Paul F. Lockheed SR-71: The Secret Missions Exposed. Oxford: Osprey Publishing, 1996.

 

Francillon, Rene J. Lockheed Aircraft Since 1913. Annapolis, Md.: Naval Institute Press, 1987.

 

Johnson, Clarence L. Kelly: More Than My Share of It All. Washington D.C.: Smithsonian Institution Press, 1985.

 

Miller, Jay. Lockheed Martin's Skunk Works. Leicester, U.K.: Midland Counties Publishing Ltd., 1995.

 

Lockheed SR-71 Blackbird curatorial file, Aeronautics Division, National Air and Space Museum.

 

DAD, 11-11-01

The only ship capable of transporting the large and heavy TerraMax 5 Phase 1 Terraformer. Powerful, efficient, and equipped for extended space missions, the HLT-1000 can get your terraforming project to your planet of choice in the safest and most successful manner ever. With interchangeable grapple arms and a myriad of cargo options, the HLT-1000 can continue to support operations as a Heavy lift cargo transport well after delivering your terraformer. With the ability to loiter on station for 3 months if needed, the HLT-1000 gives you peace of mind as you land on an unknown world because you know extraction is just a radio call away should you need it.

Some background:

The VF-1 was developed by Stonewell/Bellcom/Shinnakasu for the U.N. Spacy by using alien Overtechnology obtained from the SDF-1 Macross alien spaceship. The space-capable VF-1's combat debut was on February 7, 2009, during the Battle of South Ataria Island - the first battle of Space War I - and remained the mainstay fighter of the U.N. Spacy for the entire conflict. Introduced in 2008, the VF-1 would be out of frontline service just five years later, though.

 

The VF-1 proved to be an extremely capable craft, successfully combating a variety of Zentraedi mecha even in most sorties which saw UN Spacy forces significantly outnumbered. The versatility of the Valkyrie design enabled the variable fighter to act as both large-scale infantry and as air/space superiority fighter. The basic VF-1 was built and deployed in four minor variants (designated A, J, and S single-seater and the D two-seater/trainer) and its success was increased by continued development of various enhancements including the GBP-1S "Armored" Valkyrie exoskeleton with enhanced protection and integrated missile launchers, the so-called FAST (“Fuel And Sensor Tray”) packs that created the fully space-capable "Super" Valkyries and the additional RÖ-X2 heavy cannon pack weapon system for the VF-1S “Super Valkyrie”.

 

After the end of Space War I, the VF-1 continued to be manufactured both in the Sol system and throughout the UNG space colonies. At the end of 2015 the final rollout of the VF-1 was celebrated at a special ceremony, commemorating this most famous of variable fighters. The VF-1 Valkryie was built from 2006 to 2013 with a total production of 5,459 VF-1 variable fighters with several original variants (VF-1A = 5,093, VF-1D = 85, VF-1J = 49, VF-1S = 30, VF-1G = 12, VE-1 = 122, VT-1 = 68), even though these machines were frequently updated and modified during their career, leading to a wide range of sub-variants and different standards.

 

Although the VF-1 would be replaced in 2020 as the primary Variable Fighter of the U.N. Spacy, a long service record and continued production after the war proved the lasting worth of the design. One of these post-war designs became the VF-1EX, a replica variant of the VF-1J with up-to-date avionics and instrumentation. It was only built in small numbers in the late 2040s and was a dedicated variant for advanced training with dissimilar mock aerial and ground fighting.

 

The only operator of this type was Xaos (sometimes spelled as Chaos), a private and independent military and civilian contractor. Xaos was originally a fold navigation business that began venturing into fold wave communication and information, expanding rapidly during the 2050s and entering new business fields like flight tests and providing aggressor aircraft for military training. They were almost entirely independent from the New United Nations Spacy (NUNS) and was led by the mysterious Lady M. During the Vár Syndrome outbreak, Echo Squadron and Delta Flight and the tactical sound unit Thrones and Walküre were formed to counteract its effects in the Brísingr Globular Cluster.

 

The VF-1EX was restricted to its primary objective and never saw real combat. The replica unit retained the overall basic performance of the original VF-1 Valkyrie, the specifications being more than sufficient for training and mock combat. The only difference was the addition of the contemporary military EG-01M/MP EX-Gear system for the pilot as an emergency standard, an exoskeleton unit with personal inner-wear, two variable geometry wings, two hybrid jet/rocket engines, mechanical hardware for the head, torso, arms and legs. This feature gave the VF-1EX its new designation.

Furthermore, the VF-1EX was also outfitted with other electronic contingency functions like AI-assisted flight and remote override controls. Some of these features could be disabled according to necessity or pilot preferences. The gun pod unit was retained but was usually only loaded with paintball rounds for mock combat. For the same purpose, one of the original Mauler RÖV-20 anti-aircraft laser cannon in the "head unit" was replaced by a long-range laser target designator. AMM-1 missiles with dummy warheads or other training ordnance could be added to the wing hardpoints, but the VF-1EX was never seen being equipped this way - it remained an agile dogfighter.

  

General characteristics:

All-environment variable fighter and tactical combat Battroid. 3-mode variable transformation; variable geometry wing; vertical take-off and landing; control-configurable vehicle; single-axis thrust vectoring; three "magic hand" manipulators for maintenance use; retractable canopy shield for Battroid mode and atmospheric reentry; EG-01M/MP EX-Gear system; option of GBP-1S system, atmospheric-escape booster, or FAST Pack system.

 

Accommodation:

Single pilot in Marty & Beck Mk-7 zero/zero ejection seat

 

Dimensions:

Battroid Mode:

Height 12.68 meters

Width 7.3 meters

Length 4.0 meters

Fighter Mode:

Length 14.23 meters

Wingspan 14.78 meters (at 20° minimum sweep)

Height 3.84 meters

 

Empty weight: 13.25 metric tons

Standard take-off mass: 18.5 metric tons

MTOW: 37.0 metric tons

 

Power Plant:

2x Shinnakasu Heavy Industry/P&W/Roice FF-2001 thermonuclear reaction turbine engines, output 650 MW each, rated at 11,500 kg in standard or in overboost (225.63 kN x 2);

4x Shinnakasu Heavy Industry NBS-1 high-thrust vernier thrusters (1 x counter reverse vernier thruster nozzle mounted on the side of each leg nacelle/air intake, 1 x wing thruster roll control system on each wingtip);

18x P&W LHP04 low-thrust vernier thrusters beneath multipurpose hook/handles

 

Performance:

Battroid Mode: maximum walking speed 160 km/h

Fighter Mode: at 10,000 m Mach 2.71; at 30,000+ m Mach 3.87

g limit: in space +7

Thrust-to-weight ratio: empty 3.47; standard TOW 2.49; maximum TOW 1.24

 

Transformation:

Standard time from Fighter to Battroid (automated): under 5 sec.

Min. time from Fighter to Battroid (manual): 0.9 sec.

 

Armament:

1x Mauler RÖV-20 anti-aircraft laser cannon in the "head" unit, firing 6,000 pulses per minute

1x Howard GU-11 55 mm three-barrel Gatling gun pod with 200 RPG, fired at 1,200 rpm

4x underwing hardpoints for a wide variety of ordnance

  

The kit and its assembly:

The VF-1EX Valkyrie is a Variable Fighter introduced in the Macross Δ television series, and it's, as described above, a replica training variant that resembles outwardly the VF-1J. There's even a Hasegawa 1:72 kit from 2016 of this obscure variant.

However, what I tried to recreate is a virtual (and purely fictional/non-canonical) VF-1EX, re-skinned by someone called David L. on the basis of a virtual VF-1S 3D model with a 2 m wing span (sounds like ~1:8 scale) for the Phoenix R/C simulator software. Check this for reference: www.supermotoxl.com/projects-articles/ready-to-drive-fly-...). How bizarre can things be/become? And how sick is a hardware model of it, though...?

 

I found the complex livery very attractive and had the plan to build a 1:100 model for some years now. But it took this long to gather enough mojo to tackle this project, due to the tricolor paint scheme's complex nature...

The "canvas" for this stunt is a vintage Arii 1:100 VF-1 kit, built OOB except for some standard mods. The kit was actually a VF-1A, but I had a spare VF-1J head unit in store as a suitable replacement. Externally, some dorsal blade aerials and vanes on the nose were added, the attachment points under the wings for the pylons were PSRed away. A pilot figure was added to the cockpit because this model would be displayed in flight. As a consequence, the ventral gun pod received an adapter at its tail and I added one of my home-brew wire displays, created on the basis of the kit's OOB plastic base.

  

Painting and markings:

As mentioned above, this VF-1 is based on a re-skinned virtual R/C model, and its creator apparently took inspiration from a canonical VF fighter, namely a VF-31C "Siegfried", and specifically the "Mirage Farina Jenius Custom" version from the Macross Δ series that plays around 2051. Screenshots from the demo flight video under the link above provided various perspectives as painting reference, but the actual implementation on the tiny model caused serious headaches.

The VF-1's shapes are rather round and curvy, the model's jagged surface and small size prohibited masking. The kit is IMHO also best built and painted in single sub-assemblies, but upon closer inspection the screenshots revealed some marking inconsistencies (apparently edited from various videos?), and certain areas were left uncertain, e .g. the inside of the legs or the whole belly area. Therefore, this model is just a personal interpretation of the design, and as such I also deviated in the markings.

 

The paints became Humbrol 20 (Crimson) and 58 (Magenta), plus Revell 301 (Semi-gloss White), and they were applied with brushes. To replicate the edgy and rather fragmented pattern I initially laid down the two reds in a rather rough and thin fashion and painted the white dorsal and ventral areas. Once thoroughly dry, the white edges were quasi-masked with white decal material, either with stripes of various widths or tailored from sheet material, e. g. for the "wedges" on the wings and fins and the dorsal "swallow tail". This went more smoothly than expected, with a very convincing and clean result that i'd never had achieved with brushes alone, even with masking attempts, which would probably have led to chaos and too much paint on the model.

 

Other details like the grey leading edges or the air intakes were created with grey and black decal material, too.

No weathering was done, since the aircraft would be clean and in pristine condition, but I used a soft pencil to emphasize the engraved panel lines, esp. on white background. The gun pod became grey and the exhausts, painted in Revell 91 (Iron), were treated with graphite for a darker shade and a more metallic look.

 

Stencils came from the kit's OOB sheet, but only a few, since there was already a lot "going on" on the VF-1's hull. The flash-shaped Xaos insignia and the NUNS markings on legs and wings were printed at home - as well as the small black vernier thrusters all around the hull, for a uniform look. The USN style Modex and the small letter code on the fins came from an Colorado Decals F-5 sheet, for an aggressor aircraft.

 

Finally, the kit was sealed overall with semi-gloss acrlyic varnish (which turned out glossier than expected...) and position lights etc. added with translucent paint on top of a silver base.

  

Well, while the VF-1 was built OOB with no major mods and just some cosmetical upgrades, the paint scheme and its finish were more demanding - and I am happy that the "decal masking" trick worked so fine. The paint scheme surely is attractive, even though it IMHO does not really takes the VF-1's lines into account. Nevertheless, I am certain that there are not many models that are actually based on a virtual 1:8 scale 3D model of an iconic SF fighter, so that this VF-1EX might be unique.

 

Memory loss is not an inevitable part of the ageing process

 

The brain is capable of producing new brain cells at any age, so significant memory loss is not an inevitable result of ageing. But just as it is with muscle strength, you have to use it or lose it. Your lifestyle, health habits, and daily activities have a huge impact on the health of your brain. Whatever your age, there are many ways you can improve your cognitive skills, prevent memory loss, and protect your grey matter.

 

Furthermore, many mental abilities are largely unaffected by normal ageing, such as:

 

Your ability to do the things you’ve always done and continue to do often

The wisdom and knowledge you’ve acquired from life experience

Your innate common sense

Your ability to form reasonable arguments and judgements

  

Brain exercises to combat memory loss

 

When it comes to memory, it’s “use it or lose it.” Just as physical exercise can make and keep your body stronger, mental exercise can make your brain work better and lower the risk of mental decline. Try to find brain exercises that you find enjoyable. If you dislike what you’re doing, it won’t have the same benefit. The more pleasurable an activity is to you, the more powerful its effect will be on your brain. You can make some activities more enjoyable by appealing to your senses—by playing music during the exercise, for example, or lighting a scented candle, or rewarding yourself after you’ve finished.

 

Here are some ideas for brain exercise, from light workouts to heavy lifting:

 

Play games you are not already familiar with that involve strategy, like chess or bridge, and word games like Scrabble.

Try crossword and other word puzzles, or number puzzles such as Sudoku.

Read newspapers, magazines, and books that challenge you.

Get in the habit of learning new things: games, recipes, driving routes, a musical instrument, a foreign language.

Take a course in an unfamiliar subject that interests you. The more interested and engaged your brain, the more likely you’ll be to continue learning and the greater the benefits you’ll experience.

Take on a project that involves design and planning, such as a new garden, a quilt, or a koi pond.

 

Walking: An easy way to fight memory loss

 

New research indicates that walking six to nine miles every week can prevent brain shrinkage and memory loss. According to the American Academy of Neurology, older adults who walked between six and nine miles per week had more gray matter in their brains nine years after the start of the study than people who didn't walk as much.

 

+++ DISCLAIMER +++

Nothing you see here is real, even though the conversion or the presented background story might be based on authentic facts. BEWARE!

  

Some background:

The VF-1 was developed by Stonewell/Bellcom/Shinnakasu for the U.N. Spacy by using alien Overtechnology obtained from the SDF-1 Macross alien spaceship. Its production was preceded by an aerodynamic proving version of its airframe, the VF-X. Unlike all later VF vehicles, the VF-X was strictly a jet aircraft, built to demonstrate that a jet fighter with the features necessary to convert to Battroid mode was aerodynamically feasible. After the VF-X's testing was finished, an advanced concept atmospheric-only prototype, the VF-0 Phoenix, was flight-tested from 2005 to 2007 and briefly served as an active-duty fighter from 2007 to the VF-1's rollout in late 2008, while the bugs were being worked out of the full-up VF-1 prototype (VF-X-1).

 

The space-capable VF-1's combat debut was on February 7, 2009, during the Battle of South Ataria Island - the first battle of Space War I - and remained the mainstay fighter of the U.N. Spacy for the entire conflict. Introduced in 2008, the VF-1 would be out of frontline service just five years later, though.

 

The VF-1 proved to be an extremely capable craft, successfully combating a variety of Zentraedi mecha even in most sorties which saw UN Spacy forces significantly outnumbered. The versatility of the Valkyrie design enabled the variable fighter to act as both large-scale infantry and as air/space superiority fighter. The signature skills of U.N. Spacy ace pilot Maximilian Jenius exemplified the effectiveness of the variable systems as he near-constantly transformed the Valkyrie in battle to seize advantages of each mode as combat conditions changed from moment to moment.

 

The basic VF-1 was deployed in four minor variants (designated A, D, J, and S) and its success was increased by continued development of various enhancements including the GBP-1S "Armored" Valkyrie, FAST Pack "Super" Valkyrie and the additional RÖ-X2 heavy cannon pack weapon system for the VF-1S for additional firepower.

The FAST Pack system was designed to enhance the VF-1 Valkyrie variable fighter, and the initial V1.0 came in the form of conformal pallets that could be attached to the fighter’s leg flanks for additional fuel – primarily for Long Range Interdiction tasks in atmospheric environment. Later FAST Packs were designed for space operations.

 

The following FAST Pack 2.0 system featured two 120.000 kg class P&W+EF-2001 booster thrusters (mounted on the dorsal section of the VF-1) and two CTB-04 conformal propellant/coolant tanks (mounted on the leg/engines), since the VF-1's internal tanks could not carry enough propellant to achieve a stable orbit from Earth bases and needed the help of a booster pack to reach Low Earth Orbit. Anyway, the FAST Pack 2.0 wasn't adapted for atmospheric use, due to its impact on a Valkyrie's aerodynamics and its weight; as such, it needed to be discarded before atmospheric entry.

Included in the FAST Pack boosters and conformal tanks were six high-maneuverability vernier thrusters and two low-thrust vernier thrusters beneath multipurpose hook/handles in two dorsal-mounted NP-BP-01, as well as ten more high-maneuverability vernier thrusters and two low-thrust vernier thrusters beneath multipurpose hook/handles in the two leg/engine-mounted NP-FB-01 systems.

Granting the VF-1 a significantly increased weapons payload as well as greater fuel and thrust, Shinnakasu Heavy Industry's FAST Pack system 2.0 was in every way a major success in space combat. The first VF-1 equipped with FAST Packs was deployed in January 2010 for an interception mission.

Following first operational deployment and its effectiveness, the FAST Pack system was embraced enthusiastically by the U.N. Spacy and found wide use. By February 2010, there were already over 300+ so-called "Super Valkyries" stationed onboard the SDF-1 Macross alone.

 

The FAST Pack went through constant further development, including upgraded versions for late production and updated VF-1s (V3.0 and V4.0). Another addition to the early V2.0 variant of 2010 was the so-called “S-FAST Pack”. The S-FAST pack was originally developed at the Apollo lunar base, for the locally based VF-1 interceptor squadrons that were tasked with the defense of this important production and habitat site on the Moon, but it also found its way to other orbital stations and carriers.

 

Officially designated FAST Pack V2.1, the S-FAST Pack consisted of the standard pair of dorsal rocket boosters plus the pallets with additional maneuvering jets, sensors and weapons. The S-FAST pack added another pair of P&W+EF-2001 boosters under the inner wings, having the duty to give to fighter the power necessary to exit easily from the gravity of moons or little planets without atmosphere, and improve acceleration during combat situations. Range was also further extended, together with additional life support systems for prolonged deep space operations, or the case of emergency.

 

In order to accept the S-FAST pack and exploit its potential, the VF-1’s wings and inner wing attachment points had to be strengthened due to the additional load and propulsion. The use of the S-FAST pack also precluded the fighter from transforming into Battroid or Gerwalk mode – the underwing packs had to be jettisoned beforehand. The other standard FAST Pack 2.0 elements could still be carried, though.

 

The modfied Valkyries capable of accepting the S-FAST Pack received an additional “S” to their type designation – more than 100 VF-1s were converted or built in this deep space configuration until late 2011. Initial deployment of the S-FAST Pack was conducted through SVF-24 “Moon Shadows” in early 2010, a unit that was quickly disbanded, though, but re-formed as SVF-124 “Moon Shooters”, tasked with the defense of the lunar Apollo Base and several special missions.

 

After the end of Space War I, the VF-1 continued to be manufactured both in the Sol system and throughout the UNG space colonies. Although the VF-1 would eventually be replaced as the primary Variable Fighter of the U.N. Spacy by the more capable, but also much bigger, VF-4 Lightning III in 2020, a long service record and continued production after the war proved the lasting worth of the design.

 

The VF-1 was without doubt the most recognizable variable fighter of Space War I and was seen as a vibrant symbol of the U.N. Spacy even into the first year of the New Era 0001 in 2013. At the end of 2015 the final rollout of the VF-1 was celebrated at a special ceremony, commemorating this most famous of variable fighters. The VF-1 Valkryie was built from 2006 to 2013 with a total production of 5,459 VF-1 variable fighters with several variants (VF-1A = 5,093, VF-1D = 85, VF-1J = 49, VF-1S = 30, VF-1G = 12, VE-1 = 122, VT-1 = 68)

 

However, the fighter remained active in many second line units and continued to show its worthiness years later, e. g. through Milia Jenius who would use her old VF-1 fighter in defense of the colonization fleet - 35 years after the type's service introduction!

 

General characteristics:

All-environment variable fighter and tactical combat Battroid,

used by U.N. Spacy, U.N. Navy, U.N. Space Air Force

 

Accommodation:

Pilot only in Marty & Beck Mk-7 zero/zero ejection seat

Dimensions:

Fighter Mode:

Length 14.23 meters

Wingspan 14.78 meters (at 20° minimum sweep)

Height 3.84 meters

 

Battroid Mode:

Height 12.68 meters

Width 7.3 meters

Length 4.0 meters

Empty weight: 13.25 metric tons;

Standard T-O mass: 18.5 metric tons;

MTOW: 37.0 metric tons

 

Power Plant:

2x Shinnakasu Heavy Industry/P&W/Roice FF-2001 thermonuclear reaction turbine engines, output 650 MW each, rated at 11,500 kg in standard or in overboost (225.63 kN x 2)

4 x Shinnakasu Heavy Industry NBS-1 high-thrust vernier thrusters (1 x counter reverse vernier thruster nozzle mounted on the side of each leg nacelle/air intake, 1 x wing thruster roll control system on each wingtip);

18 x P&W LHP04 low-thrust vernier thrusters beneath multipurpose hook/handles

 

The S-FAST Pack added 4x P&W+EF-2001 booster thrusters with 120.000 kg each, plus a total of 28x P&W LHP04 low-thrust vernier thrusters

 

Performance:

Battroid Mode: maximum walking speed 160 km/h

Fighter Mode: at 10,000 m Mach 2.71; at 30,000+ m Mach 3.87

g limit: in space +7

Thrust-to-weight ratio: empty 3.47; standard T-O 2.49; maximum T-O 1.24

 

Design Features:

3-mode variable transformation; variable geometry wing; vertical take-off and landing; control-configurable vehicle; single-axis thrust vectoring; three "magic hand" manipulators for maintenance use; retractable canopy shield for Battroid mode and atmospheric reentry; option of GBP-1S system, atmospheric-escape booster, or FAST Pack system

 

Transformation:

Standard time from Fighter to Battroid (automated): under 5 sec.

Min. time from Fighter to Battroid (manual): 0.9 sec.

 

Armament:

2x internal Mauler RÖV-20 anti-aircraft laser cannon, firing 6,000 pulses per minute

1x Howard GU-11 55 mm three-barrel Gatling gun pod with 200 RPG, fired at 1,200 rds/min

 

4x underwing hard points for a wide variety of ordnance, including

12x AMM-1 hybrid guided multipurpose missiles (3/point), or

12x MK-82 LDGB conventional bombs (3/point), or

6x RMS-1 large anti-ship reaction missiles (2/outboard point, 1/inboard point), or

4x UUM-7 micro-missile pods (1/point) each carrying 15 x Bifors HMM-01 micro-missiles,

or a combination of above load-outs

 

The optional Shinnakasu Heavy Industry S-FAST Pack 2.1 augmentative space weapon system added:

6x micro-missiles in two NP-AR-01 micro-missile launcher pods (mounted rear-ward under center ventral section in Fighter mode or on lower arm sections in GERWALK/Battroid mode)

4x12 micro missiles in four HMMP-02 micro-missile launchers, one inside each booster pod

 

The kit and its assembly:

This VF-1 is another contribution to the “Old Kit” Group Build at whatifmodelers.com, running in late 2016. I am not certain about the moulds’ inception date, but since it is an ARII incarnation of this type of kit and even moulded in the early pastel green styrene, I’d think that it was produced in 1982 or 83.

 

Anyway, I love the Macross VF-1, IMHO a design masterpiece created by Shoji Kawamori and one of my favorite mecha designs ever, because it was created as a late 70ies style jet fighter that could transform into a robot in a secondary role. As a simple, purposeful military vehicle. And not like a flashy robot toy.

 

Effectively, this Super Valkyrie is a highly modified OOB kit with many donation parts, and this kit is a bit special, for several reasons. There are several 1:100 OOB kits with FAST Packs from ARII/Bandai available (and still around today), but these are normally only Battroids or Gerwalks with additional parts for the FAST kit conversion. The kit I used here is different: it is, after maybe 25 years of searching and building these kits, the #70 from the original production run. It is (so far!) the only Fighter mode kit with the additional FAST Pack parts! Must be rare, and I have never seen it in catalogues?

 

Until today, I converted my Super or Strike Valkyries from Gerwalk kits, a task that needs some improvisation esp. around the folded arms between the legs, and there’s no OOB option for an extended landing gear. The latter made this Fighter mode kit very attractive, even though the actual kit is pretty disappointing, and AFAIK this kit variant is only available as a VF-1S.

 

With the Super Valkyrie fighter kit you receive basically a Gerwalk with a standard fighter cockpit (which includes a front wheel well and an extended front wheel leg), plus extra parts. The leg/engine-mounted NP-FB-01 systems are less bulbous than the parts on the Gerwalk or Battroid kit, and the OOB dorsally mounted NP-BP-01 boosters are TINY, maybe 1:120 or even 1:144! WTF?

 

Further confusion: the kit includes a set of lower arm parts with integrated rocket launchers, but these are not necessary at all for the Fighter build?! As a kind of compensation there’s a new and exclusive element that simulates the folded arms under the ‘fuselage’ and which, as an added value, properly holds the hand gun under the fuselage. As a quirky flaw, though, the hand gun itself comes in the extended form for the Battroid/Gerwalk mode. For the fighter in flight mode, it has to be modified, but that’s easily done.

 

Anyway, with the potential option to build a Super Valkyrie with an extended landing gear, this was my route to go with this vintage kit. The Super Valkyrie already looks bulky with the FAST Pack added, but then I recently found the S-FAST Pack option with two more boosters under the wings – total overkill, but unique. And I had a spare pair of booster bulks in the stash (w/o their nozzles, though), as well as a complete pair of additional bigger standard FAST boosters that could replace the ridiculous OOB parts…

 

Building such a Super/Strike Valkyrie means building separate components, with a marriage of parts as one of the final steps. Consequently, cockpit, central fuselage with the wings and the air intakes, the folded stabilizer pack, the folded arms element with the handgun, the two legs and the four boosters plus other ordnance had to be built and painted separately.

 

Here and there, details were changed or added, e. g. a different head (a ‘J’ head for the flight leader’s aircraft with two instead of the rare, OOB ‘S’ variant with four laser cannon), covers for the main landing gear (the latter does not come with wells at all, but I did not scratch them since they are hardly recognizable when the kit is sitting on the ground), the typical blade aerials under the cockpit and the feet had to be modified internally to become truly ‘open’ jet exhausts.

 

The wing-mounted boosters received new nozzles and their front end was re-sculpted with 2C putty into a square shape, according to reference sketches. Not 100% exact, but the rest of the VF-1 isn’t either.

 

This VF-1 was also supposed to carry external ordnance and my first choice were four wing-mounted RMS-1 Anti-Ship Reaction Warheads, scratched from four 1.000 lb NATO bombs. But, once finished, I was not happy with them. So I looked for another option, and in a source book I found several laser-guided bombs and missiles, also for orbital use, and from this inspiration comes the final ordnance: four rocket-propelled kinetic impact projectiles. These are actually 1:72 JASDF LGB’s from a Hasegawa weapon set, sans aerodynamic steering surfaces and with rocket boosters added to the tail. Also not perfect, but their white color and sleek shape is a good counterpart to the FAST elements.

 

Experience from many former builds of this mecha kit family helped a lot, since the #70 kit is very basic and nothing really fits well. Even though there are not many major seams or large elements, PSR work was considerable. This is not a pleasant build, rather a fight with a lot of compromises and semi-accuracies.

Seriously, if you want a decent 1:100 VF-1, I’d rather recommend the much more modern WAVE kits (including more realistic proportions).

  

Painting and markings:

The paint scheme for this Super Valkyrie was settled upon before I considered the S-FAST Pack addition: U.N. Spacy’s SVF-124 is authentic, as well as its unique camouflage paint scheme.

The latter is a special scheme for the lunar environment where the unit was originally formed and based, with all-black undersides, a high, wavy waterline and a light grey upper surface, plus some medium grey trim and a few colorful US Navy style markings and codes.

 

My core reference is a ‘naked’ bread-and-butter VF-1A of SVF-124 in Fighter mode, depicted as a profile in a VF-1 source book from SoftBank Publishing. The colors for the FAST Pack elements are guesstimates and personal interpretations, though, since I could not find any reference for their look in this unit.

As a side note, another, later SVF-124 aircraft in a similar design is included as an option in a limited edition 1:72 VF-22S kit from Hasegawa, which is backed by CG pics in a VF-22 source book from Softbank, too.

Furthermore, SVF-124 finds mention in a Japanese modeler magazine, where the aforementioned VF-22S kit was presented in 2008. So there must be something behind the ‘Moon Shooters’ squadron.

 

According to the Hasegawa VF-22S’s painting instructions, the underside becomes black and the upper surfaces are to be painted with FS36270 (with some darker fields on the VF-22, though, similar to the USAF F-15 counter-shaded air superiority scheme, just a tad darker).

Due to the 1:100 scale tininess of my VF-1, I alternatively went for Revell 75 (RAL 7039), which is lighter and also has a brownish hue, so that the resulting aircraft would not look too cold and murky, and not resemble an USAF aircraft.

 

All FAST Pack elements were painted in a uniform dark grey (Humbrol 32), while some subtle decorative trim on the upper surfaces, e.g. the canopy frame, an anti-glare panel and a stripe behind the cockpit and decoration trim on the wings’ upper surfaces, was added with Revell 77 (RAL 7012). Overall, colors are rather dull, but IMHO very effective in the “landscape” this machine is supposed to operate, and the few colorful markings stand out even more!

 

The cockpit interior was painted in a bluish grey, with reddish brown seat cushions (late 70ies style!), and the landing gear became all white. For some added detail I painted the wings’ leading edges in a mustard tone (Humbrol 225, Mid Stone).

 

The kit received some weathering (black ink wash, drybrushing on panels) and extra treatment of the panel lines – even though the FAST Pack elements hide a lot of surface or obscure view.

 

More color and individuality came with the markings. The standard decals like stencils or the U.N. Spacy insignia come from the kit’s and some other VF-1s’ OOB sheets.

Based on the SVF-124 VF-1 profile and taking the basic design a bit further, I used dull red USAF 45° digits for the 2nd flight leader’s “200” modex and the Apollo Base’s code “MA” on the dorsal boosters. Some discreet red trim was also applied to the FAST Packs – but only a little.

 

Since all of SVF-124’s aircraft are rumored to carry personal markings, including nose art and similar decorations, I tried to give this VF-1JS a personal note: the pin-up badges on the dorsal boosters come from a Peddinghouse decal sheet for Allied WWII tanks, placed on a silver roundel base. Unfortunately (and not visible before I applied them) the pin-up decal was not printed on a white basis, so that the contrast on the silver is not very strong, but I left it that way. Additionally, the tagline “You’re a$$ next, Jerry” (which IS printed in opaque white…?) was added next to the artwork – but it’s so tiny that you have to get really close to decipher it at all…

 

Finally, after some soot stains around the exhausts and some vernier nozzels with graphite, the kit received a coat of matt acrylic varnish.

 

Building this vintage VF-1 kit took a while and a lot of effort, but I like the result: with the S-FAST Pack, the elegant VF-1 turned into a massive space fighter hulk! The normal Super Valkyries already look very compact and purposeful, but this here is truly menacing. Especially when standing on its own feet/landing gear, with its nose-down stance and the small, original wheels, this thing reminds of a Space Shuttle that had just landed.

 

Good that I recently built a simple VF-1 fighter as a warm-up session. ARII’s kit #70 is not a pleasant build, rather a fight with the elements and coupled with a lot of compromises – if you want a Super Valkyrie Fighter in 1:100, the much more modern WAVE kit is IMHO the better option (and actually not much more pricey than this vintage collector’s item). But for the vintage feeling, this exotic model kit was just the right ticket, and it turned, despite many weaknesses and rather corny details, into an impressive fighter. Esp. the lunar camouflage scheme looks odd, but very unique and purposeful.

 

Anyway, with so many inherent flaws of the ARII kit, my former method of converting a pure (and much more common) Gerwalk kit into a space-capable VF-1 fighter is not less challenging and complicated than trying to fix this OOB option into a decent model. :-/

Some background:

The VF-1 was developed by Stonewell/Bellcom/Shinnakasu for the U.N. Spacy by using alien Overtechnology obtained from the SDF-1 Macross alien spaceship. The space-capable VF-1's combat debut was on February 7, 2009, during the Battle of South Ataria Island - the first battle of Space War I - and remained the mainstay fighter of the U.N. Spacy for the entire conflict. Introduced in 2008, the VF-1 would be out of frontline service just five years later, though.

 

The VF-1 proved to be an extremely capable craft, successfully combating a variety of Zentraedi mecha even in most sorties which saw UN Spacy forces significantly outnumbered. The versatility of the Valkyrie design enabled the variable fighter to act as both large-scale infantry and as air/space superiority fighter. The basic VF-1 was built and deployed in four minor variants (designated A, J, and S single-seater and the D two-seater/trainer) and its success was increased by continued development of various enhancements including the GBP-1S "Armored" Valkyrie exoskeleton with enhanced protection and integrated missile launchers, the so-called FAST (“Fuel And Sensor Tray”) packs that created the fully space-capable "Super" Valkyries and the additional RÖ-X2 heavy cannon pack weapon system for the VF-1S “Super Valkyrie”.

 

After the end of Space War I, the VF-1 continued to be manufactured both in the Sol system and throughout the UNG space colonies. At the end of 2015 the final rollout of the VF-1 was celebrated at a special ceremony, commemorating this most famous of variable fighters. The VF-1 Valkryie was built from 2006 to 2013 with a total production of 5,459 VF-1 variable fighters with several original variants (VF-1A = 5,093, VF-1D = 85, VF-1J = 49, VF-1S = 30, VF-1G = 12, VE-1 = 122, VT-1 = 68), even though these machines were frequently updated and modified during their career, leading to a wide range of sub-variants and different standards.

 

Although the VF-1 would be replaced in 2020 as the primary Variable Fighter of the U.N. Spacy, a long service record and continued production after the war proved the lasting worth of the design. One of these post-war designs became the VF-1EX, a replica variant of the VF-1J with up-to-date avionics and instrumentation. It was only built in small numbers in the late 2040s and was a dedicated variant for advanced training with dissimilar mock aerial and ground fighting.

 

The only operator of this type was Xaos (sometimes spelled as Chaos), a private and independent military and civilian contractor. Xaos was originally a fold navigation business that began venturing into fold wave communication and information, expanding rapidly during the 2050s and entering new business fields like flight tests and providing aggressor aircraft for military training. They were almost entirely independent from the New United Nations Spacy (NUNS) and was led by the mysterious Lady M. During the Vár Syndrome outbreak, Echo Squadron and Delta Flight and the tactical sound unit Thrones and Walküre were formed to counteract its effects in the Brísingr Globular Cluster.

 

The VF-1EX was restricted to its primary objective and never saw real combat. The replica unit retained the overall basic performance of the original VF-1 Valkyrie, the specifications being more than sufficient for training and mock combat. The only difference was the addition of the contemporary military EG-01M/MP EX-Gear system for the pilot as an emergency standard, an exoskeleton unit with personal inner-wear, two variable geometry wings, two hybrid jet/rocket engines, mechanical hardware for the head, torso, arms and legs. This feature gave the VF-1EX its new designation.

Furthermore, the VF-1EX was also outfitted with other electronic contingency functions like AI-assisted flight and remote override controls. Some of these features could be disabled according to necessity or pilot preferences. The gun pod unit was retained but was usually only loaded with paintball rounds for mock combat. For the same purpose, one of the original Mauler RÖV-20 anti-aircraft laser cannon in the "head unit" was replaced by a long-range laser target designator. AMM-1 missiles with dummy warheads or other training ordnance could be added to the wing hardpoints, but the VF-1EX was never seen being equipped this way - it remained an agile dogfighter.

  

General characteristics:

All-environment variable fighter and tactical combat Battroid. 3-mode variable transformation; variable geometry wing; vertical take-off and landing; control-configurable vehicle; single-axis thrust vectoring; three "magic hand" manipulators for maintenance use; retractable canopy shield for Battroid mode and atmospheric reentry; EG-01M/MP EX-Gear system; option of GBP-1S system, atmospheric-escape booster, or FAST Pack system.

 

Accommodation:

Single pilot in Marty & Beck Mk-7 zero/zero ejection seat

 

Dimensions:

Battroid Mode:

Height 12.68 meters

Width 7.3 meters

Length 4.0 meters

Fighter Mode:

Length 14.23 meters

Wingspan 14.78 meters (at 20° minimum sweep)

Height 3.84 meters

 

Empty weight: 13.25 metric tons

Standard take-off mass: 18.5 metric tons

MTOW: 37.0 metric tons

 

Power Plant:

2x Shinnakasu Heavy Industry/P&W/Roice FF-2001 thermonuclear reaction turbine engines, output 650 MW each, rated at 11,500 kg in standard or in overboost (225.63 kN x 2);

4x Shinnakasu Heavy Industry NBS-1 high-thrust vernier thrusters (1 x counter reverse vernier thruster nozzle mounted on the side of each leg nacelle/air intake, 1 x wing thruster roll control system on each wingtip);

18x P&W LHP04 low-thrust vernier thrusters beneath multipurpose hook/handles

 

Performance:

Battroid Mode: maximum walking speed 160 km/h

Fighter Mode: at 10,000 m Mach 2.71; at 30,000+ m Mach 3.87

g limit: in space +7

Thrust-to-weight ratio: empty 3.47; standard TOW 2.49; maximum TOW 1.24

 

Transformation:

Standard time from Fighter to Battroid (automated): under 5 sec.

Min. time from Fighter to Battroid (manual): 0.9 sec.

 

Armament:

1x Mauler RÖV-20 anti-aircraft laser cannon in the "head" unit, firing 6,000 pulses per minute

1x Howard GU-11 55 mm three-barrel Gatling gun pod with 200 RPG, fired at 1,200 rpm

4x underwing hardpoints for a wide variety of ordnance

  

The kit and its assembly:

The VF-1EX Valkyrie is a Variable Fighter introduced in the Macross Δ television series, and it's, as described above, a replica training variant that resembles outwardly the VF-1J. There's even a Hasegawa 1:72 kit from 2016 of this obscure variant.

However, what I tried to recreate is a virtual (and purely fictional/non-canonical) VF-1EX, re-skinned by someone called David L. on the basis of a virtual VF-1S 3D model with a 2 m wing span (sounds like ~1:8 scale) for the Phoenix R/C simulator software. Check this for reference: www.supermotoxl.com/projects-articles/ready-to-drive-fly-...). How bizarre can things be/become? And how sick is a hardware model of it, though...?

 

I found the complex livery very attractive and had the plan to build a 1:100 model for some years now. But it took this long to gather enough mojo to tackle this project, due to the tricolor paint scheme's complex nature...

The "canvas" for this stunt is a vintage Arii 1:100 VF-1 kit, built OOB except for some standard mods. The kit was actually a VF-1A, but I had a spare VF-1J head unit in store as a suitable replacement. Externally, some dorsal blade aerials and vanes on the nose were added, the attachment points under the wings for the pylons were PSRed away. A pilot figure was added to the cockpit because this model would be displayed in flight. As a consequence, the ventral gun pod received an adapter at its tail and I added one of my home-brew wire displays, created on the basis of the kit's OOB plastic base.

  

Painting and markings:

As mentioned above, this VF-1 is based on a re-skinned virtual R/C model, and its creator apparently took inspiration from a canonical VF fighter, namely a VF-31C "Siegfried", and specifically the "Mirage Farina Jenius Custom" version from the Macross Δ series that plays around 2051. Screenshots from the demo flight video under the link above provided various perspectives as painting reference, but the actual implementation on the tiny model caused serious headaches.

The VF-1's shapes are rather round and curvy, the model's jagged surface and small size prohibited masking. The kit is IMHO also best built and painted in single sub-assemblies, but upon closer inspection the screenshots revealed some marking inconsistencies (apparently edited from various videos?), and certain areas were left uncertain, e .g. the inside of the legs or the whole belly area. Therefore, this model is just a personal interpretation of the design, and as such I also deviated in the markings.

 

The paints became Humbrol 20 (Crimson) and 58 (Magenta), plus Revell 301 (Semi-gloss White), and they were applied with brushes. To replicate the edgy and rather fragmented pattern I initially laid down the two reds in a rather rough and thin fashion and painted the white dorsal and ventral areas. Once thoroughly dry, the white edges were quasi-masked with white decal material, either with stripes of various widths or tailored from sheet material, e. g. for the "wedges" on the wings and fins and the dorsal "swallow tail". This went more smoothly than expected, with a very convincing and clean result that i'd never had achieved with brushes alone, even with masking attempts, which would probably have led to chaos and too much paint on the model.

 

Other details like the grey leading edges or the air intakes were created with grey and black decal material, too.

No weathering was done, since the aircraft would be clean and in pristine condition, but I used a soft pencil to emphasize the engraved panel lines, esp. on white background. The gun pod became grey and the exhausts, painted in Revell 91 (Iron), were treated with graphite for a darker shade and a more metallic look.

 

Stencils came from the kit's OOB sheet, but only a few, since there was already a lot "going on" on the VF-1's hull. The flash-shaped Xaos insignia and the NUNS markings on legs and wings were printed at home - as well as the small black vernier thrusters all around the hull, for a uniform look. The USN style Modex and the small letter code on the fins came from an Colorado Decals F-5 sheet, for an aggressor aircraft.

 

Finally, the kit was sealed overall with semi-gloss acrlyic varnish (which turned out glossier than expected...) and position lights etc. added with translucent paint on top of a silver base.

  

Well, while the VF-1 was built OOB with no major mods and just some cosmetical upgrades, the paint scheme and its finish were more demanding - and I am happy that the "decal masking" trick worked so fine. The paint scheme surely is attractive, even though it IMHO does not really takes the VF-1's lines into account. Nevertheless, I am certain that there are not many models that are actually based on a virtual 1:8 scale 3D model of an iconic SF fighter, so that this VF-1EX might be unique.

 

+++ DISCLAIMER +++

Nothing you see here is real, even though the model, the conversion or the presented background story might be based on historical facts. BEWARE!

  

Some background:

Tyne was the second of the five River-class light cruisers in the Royal Navy, which were introduced during the interwar period and played, after modifications, an active role in World War II, especially in the Mediterranean theatre of operations.

 

After the construction of the Danae-class cruiser, the demerits of the small cruiser concept became apparent. At the end of 1917, plans for an additional six C-class vessels, plus three new-design 7,200 ton-class scouting cruisers were shelved, in favor of an intermediate 5,500 ton-class vessel which could be used as both a long-range, high speed scout ship, and also as a command vessel for destroyer or submarine flotillas. The resulting River-class vessels were essentially enlarged versions of the Danae-class cruisers, with greater speed, range, and weaponry. With improvements in geared-turbine engine technology, the River-class vessels were capable of the high speed of 36 knots (67 km/h), and a range of 9,000 nmi (17,000 km) at 10 kn (12 mph; 19 km/h). The number of BL 6-inch (152.4 mm) L/45 Mark XII guns was increased from only three to seven in single mounts and provision was made for 48 naval mines. However, the four triple torpedo launchers on the Danae-class were reduced to just two double launchers, and the River-class remained highly deficient in anti-aircraft protection, with only two QF 3 in 20 cwt L/45 Mk. I and two QF 2-pounder L/39 Mk. II guns. A total of eight ships were ordered, but, with less pressure after the end of WWI, only five were built and finished.

 

The first River-class ship, H.M.S. “Trent”, was laid down in December 1918 and launched in August 1919. H.M.S. “Tyne” was the second cruiser of this new class, laid down 8 July 1919, launched 24 September 1920 and completed at Chatham Royal Dockyard 2 June 1922. Completed too late to see action in the First World War, “Tyne” was initially assigned to operate in the Baltic Sea against the Bolshevik revolutionaries in Russia. She was then on detached service in the West Indies. Following this assignment, she was attached to the 1st Light Cruiser Squadron of the Atlantic Fleet for the following five years. 1923/24, “Tyne” became a member of the Cruise of the Special Service Squadron, also known as the “Empire Cruise”. Following this tour, she went with the squadron to the Mediterranean for the next few years.

 

In May 1928 “Tyne” was assigned to the North America and West Indies Station, based at the Royal Naval Dockyard in Bermuda. She ran aground on 2 July 1928 on the Thrum Cap Shoal, 5 nautical miles (9.3 km) off Halifax, Nova Scotia, Canada, and was badly damaged, suffering the breach of her engine room and of one of her boiler rooms. She was abandoned by most of her 445 crew, the officers remaining on board. Subsequently, all her guns and torpedo tubes and much of her other equipment had to be removed to lighten her. She was finally refloated on 11 July 1928 and towed off by H.M.S. “Despatch” and several tugs. She was repaired throughout 1929 and then reduced to the reserve.

 

In 1930, however, due to a shortage of ships at foreign theatres of operation, she was reactivated and transferred back to the America and West Indies Station. During 1931-1933 she served with the South American Division, and in 1934 she relieved the cruiser “Curlew” in the Mediterranean and was reassigned to the 3rd Cruiser Squadron. In 1935 she returned to Britain to be paid off into the reserve, but “Tyne” was kept active in British coastal waters for cadet training.

 

On the outbreak of the Second World War, “Tyne” was recommissioned and thoroughly modernized, since the original armament and other equipment had become obsolete by 1939. All five River-class ships were re-designed as light trade protection cruisers and were outfitted with new, state-of-the-art equipment and armament, including six new and very compact turrets. Pairs were placed at the bow and at the stern each, with another two placed singly at port and starboard amidships. Each was armed with twin 5.25-inch (133 mm) guns in high angle mountings. These new, quick-firing weapons were primarily surface weapons, but it was intended to fire the heaviest shell suitable for anti-aircraft defense, so that the ships could be used for convoy protection from aerial attacks.

The ballistic performance of the QF 5.25 was very good, with a maximum range of 24,070 yd (22,010 m) at 45 degrees with an 80 lb (36.3 kg) HE shell. In comparison, the contemporary French 138 mm (5.4 in) Mle 1934 guns as used on the Mogador-class destroyers had a maximum range of 21,872 yards (20,000 m) at 30 degrees with an 88 lb (39.9 kg) SAP shell, and the Italian 135/45 mm gun as used on the Capitani Romani-class cruisers had a maximum range of 21,435 yards (19,600 m) at 45 degrees with a 72.1 lb (32.7 kg) AP shell.

The new turrets were far more modern in design than previous light cruiser turrets and offered efficient loading up to 70 degrees to provide the intended dual-purpose capability. Furthermore, “Tyne” was, like its revamped sister ships, outfitted with four twin QF 2-pounder (40 mm) "pom-poms" and a pair of triple 21-inch (533 mm) torpedo tube launchers, mounted under the main deck. The latter carried a steam catapult for a reconnaissance waterplane, initially a Fairey Swordfish on floats but later replaced by a Supermarine Walrus amphibious flying boat. The depth charge racks were augmented by two new launchers.

 

After her modifications at Portsmouth Royal Dockyard, field tests in the Channel and receiving a light disruptive Admiralty paint scheme, “Tyne” joined the 2nd Cruiser Squadron, escorting convoys to Scandinavia and engaged in the hunt for the German battleships Scharnhorst and Gneisenau. After the Norwegian Campaign she participated in the operations hunting the German battleship Bismarck and, together with the cruiser “Kenya”, intercepted one of the German supply ships, “Belchen”, on 3 June 1941.

 

Between July and August 1941, as part of Force K with the Home Fleet, she was involved in “Operation Gauntlet”, with operations to Spitzbergen and Bear Island. After one of these sorties, in company with the cruiser “Nigeria”, she intercepted a German troop convoy off Northern Norway, and the German ship “Bremse” was sunk. Later that year she was transferred to the Mediterranean and arrived in Alexandria on 21 October 1941 to join a new Force K, where the ship received a new high-contrast paint scheme, typical for this theatre of operations.

 

On 9 November 1941, Force K, consisting of “Tyne”,”Aurora”, “Penelope”, “Lance” and “Lively”, she was involved in the destruction of the Beta Convoy. In the resulting battle the Italian destroyer “Fulmine” was sunk, as well as the German transports “Duisburg” and “San Marco”, the Italian transports “Maria”, “Sagitta” and “Rina Corrado”, and the Italian “Conte di Misurata” and “Minatitlan”. The Italian destroyers “Grecale” and “Euro” were damaged.

 

On 24 November Force K, intercepted an Axis convoy about 100 nautical miles west of Crete. The Axis convoy was bound from the Aegean to Benghazi. The two German transports in the convoy, “Maritza” and “Procida”, were both sunk by H.M.S. “Penelope” and H.M.S. “Lively” despite the presence of the Italian torpedo boats “Lupo” and “Cassiopea”. On 1 December 1941 Force K, with “Tyne”, “Penelope” and ”Lively”, attacked the Mantovani Convoy. The Italian destroyer “Alvise Da Mosto” and the sole cargo ship “Mantovani” were sunk. H.M.S. “Tyne” next participated in the First Battle of Sirte on 17 December 1941. On 19 December, while steaming off Tripoli, she was heavily damaged in a mine field and was forced to retire to Malta for hull repairs.

 

After repairs, which lasted several months into summer 1942, she returned to service in the MTO and joined Force H. In November she became part of the Centre Task Force for the Landings in North Africa, Operation Torch. Off Oran, she engaged the Vichy French destroyers “Tramontane” and “Tornad”e on 8 November 1942, damaging the former so badly that it had to be beached. The following day she badly damaged the destroyer “Épervier” and drove it ashore. By early December 1942 she was operating as part of Force Q at Bône against the Axis evacuation and supply convoys between Trapani and Tunis.

 

However, “Tyne” was hit on 20 December 1942 off Trapani (Sicily) by an air-dropped torpedo. She caught fire, had two of her turrets out of action and was badly flooded. Later that day she was attacked once more by German dive-bombers, and a fatal bomb hit at the ship’s stern eventually led to her loss the following day. 115 men were killed through the attacks, the rest, more than two-thirds of the crew, was rescued.

 

All River-class ships had a very active war career and proved to be satisfactory in service, even though they were hardly a match for full-fledged battleships and worked best in conjunction with other ships. Especially in the Mediterranean they were very effective in protecting crucial convoys to Malta and even managed to see off some ships of the Italian Royal Navy. However, their outdated WWI machinery became their Achilles heel and limited their potential, and the relatively light main guns lacked range and firepower to take on major enemy ships their own.

From 1940 on the ships were to be replaced by the much more modern and better-equipped new Dido-class cruisers, but a shortage of guns for them, due to difficulties in manufacturing them, delayed their introduction so that the River-class cruisers had to soldier on. Two ships, “Tyne” and “Thames”, were lost, and the three post-war survivors “Trent”, “Severn” and “Mersey”, were immediately put into reserve after the end of hostilities in Europe and quickly broken up.

  

General characteristics:

Displacement: 5,100 long tons (5,200 t) (standard)

Length: 500 ft (152.4 m)

Beam: 47 ft (14.2 m)

Draft: 16 ft (4.8 m)

Draught: 12 ft 6 in (3.8 m) (deep)

Armor: Belt: 64 mm (3 in), Deck: 29 mm (1 in)

Complement: 450

 

Propulsion:

12× Admiralty boilers with 4× geared steam turbines, developing 90,000 shp (67,000 kW)

and driving four shafts

 

Performance:

Top speed: 36 knots (67 km/h; 41 mph)

Range: 5,000 nmi (9,300 km; 5,800 mi) at 14 kn (26 km/h; 16 mph)

 

Armament (after conversion):

12× 5.25 guns (133 mm) 50 caliber guns in six twin turrets

4× twin QF 2-pounder (40 mm) "pom-pom" AA guns in powered mounts

2× triple 21-inch (533 mm) torpedo tubes

2× throwers and 2× racks astern with 48 depth charges

  

The kit and its assembly:

The Royal Navy’s River-class light cruisers never existed. These fictional interwar ships were based on the Dido-class cruisers’ concept, just placed in an earlier generation and realized on the basis of an old/outdated ship. Inspiration came with an aftermarket set of six 1:700 white metal turrets that I came across recently, and I wanted to use it to build something like the American Atlanta-class light cruisers with a specialized AA armament.

 

However, this armament called for a suitable and bigger hull than my former destroyer builds, and I was eventually able to hunt down a cheap Tamiya kit of a Japanese Kuma-class light cruiser as starting point. It was perfect in size (almost exactly as big as a Dido-class cruiser!), shape and time frame, even though I I basically only used the kit’s single-piece hull as starting point. I had to modify the superstructures thoroughly to adapt the Japanese ship to the new role and also to a more Western layout and silhouette.

For instance, the typically Japanese tall “pagoda” bridge/command section of that era had to disappear, and I changed the superstructures almost completely, because the new twin turrets needed much more space than the small single guns of the Kuma cruiser. I also wanted to place them at different levels, and this called for suitable staggered platforms, too.

 

Initially there was the plan to mount the six turrets in groups of three at both bow and stern, but it was soon clear that this would not work – this arrangement would have been too long and too high, too, so that I went with two staggered pairs. I also wanted to give the ship – unlike the American Atlanta-class ships – a catapult for an on-board aircraft, and this required some free space on deck.

With this framework I scratched new/additional superstructures, using leftover pieces from the two recently built Matchbox K-class destroyers and from a Revell H.M.S. Ark Royal carrier. Everything evolved through trial-and error, in an attempt to find a plausible layout for all the deck equipment. The lowered hull section for the Kuma-class’ front torpedo tubes was filled with a cabin and re-purposed for lifeboats. Then the initially continuous superstructure was split to make room for the steam catapult amidships at deck level. The rear turrets eventually found their final places on a separate superstructure that would also carry the secondary mast and the crane for the floatplane, and I mounted the last two turrets in lateral positions (again somewhat inspired by the Atlanta-class arrangement with similar positions), above the Kuma-class’ openings for the rear torpedo launch tubes. These did not make sense at this position anymore, so that the OOB openings were closed/filled and moved further forward, under the new “flight deck”. Some PSR had to be done, too, in order to blend some disparate donor parts and fill the worst gaps. Therefore, the finish is certainly not as crisp as an OOB model – but I think that these flaws remained on an acceptable level.

 

Once the general deck layout had been settled, detail work began. This included a re-arrangement of bridge, masts and funnels, and the main deck had to offer enough space for the re-located catapult, together with the turrets in the side positions, lifeboats and AA stations, which found their place at deck level and in two twin alcoves in higher positions. Fiddly stuff, and I must admit that “creating” such a battleship is conceptually not easy.

The aircraft on board is actually the OOB Kawanishi E7K floatplane from the Kuma-class cruiser kit – but it looks similar enough to a Swordfish that this illusion could be easily supported with a suitable paint scheme.

  

Painting and markings:

I used the opportunity to apply another typical Royal Navy paint scheme, a so-called “Alexandria-style” pattern. This was a high-contrast scheme, sometimes described as consisting of black and white, but it was typically made up from 507a (Dark Grey) and 507c (Light Grey). It had been christened after the dockyard where it had been initially applied, and it was actually not a defined pattern (like the Admiralty schemes, which had been designed at offices by people who frequently had no practical naval experience!), but rather a common but individual application of standard paints that had been in ample supply at most dockyards! The ships had to be painted with what was at hand, and so the disruptive scheme caught on and was applied, like Mountbatten Pink, to a considerable number of British ships operating in the MTO. This two-tone scheme was not intended to conceal the ships, but rather to confuse the observer concerning speed, direction and what the ship actually was.

 

The pattern I applied to the model was loosely based on what the cruiser H.M.S. Devonshire carried in 1941, a kind of zebra pattern with wide, well-defined block stripes. As a visual gimmick these stripes were kind of “mirrored” along a line on the hull, as if reflected by the water and therefore making assessing size or distance even more difficult.

The paints are Humbrol 147 (Light Grey, FS 36495) and 27 (Sea Grey). The deck was painted as if the wooden areas had not been overpainted yet and allowed to weather, so that the once-holystoned, yellow-ish light wood had become dull and rather grey-ish. I used Humbrol 168 (RAF Hemp) and Revell 87 (Beige) as basis, and some light shading with thinned sepia ink was done to enhance the wooden look – and it’s nice contrast to the rather cold, grey camouflage. Metal decks, turret tops and the bow area were painted with Revell 47, simulating 507b (Medium Grey). Areas around the bridge were painted with Humbrol 62 (Leather) to simulate Corticene coating.

 

I originally wanted to paint the model in separate elements before final assembly, but this was not possible due to the many adjustments. The model was slightly weathered with a highly thinned black ink wash. Some Sienna Brown water paint was used for rust stains here and there. Portholes along the hull and on the superstructures were created with a thin black felt tip pen. The same tool was used to paint the muzzles of the guns. The crisp black boot topping was easy to create through the kit’s separate waterline bottom – OOB it comes in red, and it just had to be re-painted.

The kit’s segments were sealed with a coat of acrylic matt varnish before final assembly. Finally, rigging with heated and extended dark grey sprue material was done and paper flags were added.

  

It is not obvious, but the fictional H.M.S. “Tyne” took more scratchwork and mods than one would expect – it was/is almost a scratch build on the basis of a stock cruiser hull. More or less, the whole superstructure was re-arranged and the whole armament is new, but I think that the outcome looks quite plausible. The camouflage – even though only consisting of two shades of grey - looks interesting, too, and I think that the confusing effect becomes obvious in some of the beauty pics.

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Electronics hobby

  

Designing and building a high power amplifier capable of driving low impedance (as low as 2 Ohm’s @ 50 Vpp) loads.

  

www.diyaudio.com/ see alias FdW

  

History of DIY audio

 

Audio DIY came to prominence in the 50s to 60s, as audio reproduction was relatively new and the technology "complex," audio reproduction equipment, and in particular high performance equipment, was not offered at the retail level. Kits and designs were available for consumers to build their own equipment. Famous vacuum tube kits from Dynaco, Heathkit, and McIntosh, as well as solid state (transistor) kits from Hafler allowed for consumers to build their own hi fidelity systems. Books and magazines were published which explained new concepts regarding the design and operation of vacuum tube and (later) transistor circuits.

 

While audio equipment has become easily accessible in the current day and age, there still exists an interest in building one's own equipment, including amplifiers, speakers, preamplifiers, and even CD players and turntables. Today, a network of companies, parts vendors, and on-line communities exist to foster this interest. DIY is especially active in loudspeaker and in tube amplification. Both are relatively simple to design and fabricate without access to sophisticated industrial equipment. Both enable the builder to pick and choose between various available parts, on matters of price as well as quality, allow for extensive experimentation, and offer the chance to use exotic or highly labor-intensive solutions, which would be expensive for a manufacturer to implement, but only require personal labor by the DIYer, which is a source of satisfaction to them.

  

en.wikipedia.org/wiki/DIY_audio

CA. SEA OTTERS: MONTEREY BAY

 

The Southern or California Sea Otter (Enhydra lutris nereis) has been listed as a threatened species under the Endangered Species Act since 1977.

•Sea otters are highly specialized marine mammals capable of living their entire lives without ever having to leave the ocean, have the densest fur of any mammal and are one of the few marine species to use tools.

•Sea otters are an apex predator of the near shore ecosystem. The species is considered a keystone species because of their critical importance to the health and stability of the near shore marine ecosystem.

•They are also considered a sentinel species because their health reflects that of California’s coastal oceans.

•The southern sea otter population has exhibited high levels of mortality in recent years. Scientists attribute up to 40 percent of southern sea otter mortality to infectious diseases alone, many of which are known to have anthropogenic causes and land-sea linkages.

•The single greatest threat to the sea otter is an oil spill. One large oil spill in central California could be catastrophic, with the potential of driving the entire southern sea otter population into extinction.

 

Description

•The sea otter is one of the smallest marine mammals, but one of the largest members of the family Mustelidae, a group that includes skunks and weasels among others.

•Adult males reach an average length of 4.5 feet (1.4 m) with a typical weight between 50 and 100 lbs. (23 to 45 kg), while adult females reach an average length of 4 feet (1.2 m) and typically weigh 45 lbs. (20 kg).

•It has a highly buoyant, elongated body, blunt snout and small, wide head.

•Sea otters have an acute sense of smell and taste and have good vision both above and below the water surface. They also rely heavily on their sense of touch.

•Sea otters exhibit numerous adaptations, which help them survive in their challenging marine environment. Long whiskers help them to detect vibrations in murky waters and sensitive forepaws, with retractable claws, help them to groom, locate and capture prey underwater, and use tools.

•When underwater, they can close their nostrils and small ears.

•Hearing is one sense that is not yet fully understood, although studies suggest they are particularly sensitive to high-frequency sounds.

•Their teeth are unique for a mammal in that they are blunt and designed for crushing, rather than being sharp for tearing like most marine mammals are equipped with.

•With the exception of its nose and pads of its paws, the sea otter’s body is covered in dense fur. The fur consists of two layers. The short, brown under fur can be as dense as 1 million hairs per square inch, making its fur the densest of any mammal. By comparison, we only have about 100,000 hairs in total on our heads.

 

+++ DISCLAIMER +++

Nothing you see here is real, even though the conversion or the presented background story might be based on authentic facts. BEWARE!

  

Some background:

The VF-1 was developed by Stonewell/Bellcom/Shinnakasu for the U.N. Spacy by using alien Overtechnology obtained from the SDF-1 Macross alien spaceship. Its production was preceded by an aerodynamic proving version of its airframe, the VF-X. Unlike all later VF vehicles, the VF-X was strictly a jet aircraft, built to demonstrate that a jet fighter with the features necessary to convert to Battroid mode was aerodynamically feasible. After the VF-X's testing was finished, an advanced concept atmospheric-only prototype, the VF-0 Phoenix, was flight-tested from 2005 to 2007 and briefly served as an active-duty fighter from 2007 to the VF-1's rollout in late 2008, while the bugs were being worked out of the full-up VF-1 prototype (VF-X-1).

 

The space-capable VF-1's combat debut was on February 7, 2009, during the Battle of South Ataria Island - the first battle of Space War I - and remained the mainstay fighter of the U.N. Spacy for the entire conflict. Introduced in 2008, the VF-1 would be out of frontline service just five years later, though.

 

The VF-1 proved to be an extremely capable craft, successfully combating a variety of Zentraedi mecha even in most sorties which saw UN Spacy forces significantly outnumbered. The versatility of the Valkyrie design enabled the variable fighter to act as both large-scale infantry and as air/space superiority fighter. The signature skills of U.N. Spacy ace pilot Maximilian Jenius exemplified the effectiveness of the variable systems as he near-constantly transformed the Valkyrie in battle to seize advantages of each mode as combat conditions changed from moment to moment.

 

The basic VF-1 was deployed in four minor variants (designated A, D, J, and S) and its success was increased by continued development of various enhancements including the GBP-1S "Armored" Valkyrie, FAST Pack "Super" Valkyrie and the additional RÖ-X2 heavy cannon pack weapon system for the VF-1S for additional firepower.

The FAST Pack system was designed to enhance the VF-1 Valkyrie variable fighter, and the initial V1.0 came in the form of conformal pallets that could be attached to the fighter’s leg flanks for additional fuel – primarily for Long Range Interdiction tasks in atmospheric environment. Later FAST Packs were designed for space operations.

 

The following FAST Pack 2.0 system featured two 120.000 kg class P&W+EF-2001 booster thrusters (mounted on the dorsal section of the VF-1) and two CTB-04 conformal propellant/coolant tanks (mounted on the leg/engines), since the VF-1's internal tanks could not carry enough propellant to achieve a stable orbit from Earth bases and needed the help of a booster pack to reach Low Earth Orbit. Anyway, the FAST Pack 2.0 wasn't adapted for atmospheric use, due to its impact on a Valkyrie's aerodynamics and its weight; as such, it needed to be discarded before atmospheric entry.

Included in the FAST Pack boosters and conformal tanks were six high-maneuverability vernier thrusters and two low-thrust vernier thrusters beneath multipurpose hook/handles in two dorsal-mounted NP-BP-01, as well as ten more high-maneuverability vernier thrusters and two low-thrust vernier thrusters beneath multipurpose hook/handles in the two leg/engine-mounted NP-FB-01 systems.

Granting the VF-1 a significantly increased weapons payload as well as greater fuel and thrust, Shinnakasu Heavy Industry's FAST Pack system 2.0 was in every way a major success in space combat. The first VF-1 equipped with FAST Packs was deployed in January 2010 for an interception mission.

Following first operational deployment and its effectiveness, the FAST Pack system was embraced enthusiastically by the U.N. Spacy and found wide use. By February 2010, there were already over 300+ so-called "Super Valkyries" stationed onboard the SDF-1 Macross alone.

 

The FAST Pack went through constant further development, including upgraded versions for late production and updated VF-1s (V3.0 and V4.0). Another addition to the early V2.0 variant of 2010 was the so-called “S-FAST Pack”. The S-FAST pack was originally developed at the Apollo lunar base, for the locally based VF-1 interceptor squadrons that were tasked with the defense of this important production and habitat site on the Moon, but it also found its way to other orbital stations and carriers.

 

Officially designated FAST Pack V2.1, the S-FAST Pack consisted of the standard pair of dorsal rocket boosters plus the pallets with additional maneuvering jets, sensors and weapons. The S-FAST pack added another pair of P&W+EF-2001 boosters under the inner wings, having the duty to give to fighter the power necessary to exit easily from the gravity of moons or little planets without atmosphere, and improve acceleration during combat situations. Range was also further extended, together with additional life support systems for prolonged deep space operations, or the case of emergency.

 

In order to accept the S-FAST pack and exploit its potential, the VF-1’s wings and inner wing attachment points had to be strengthened due to the additional load and propulsion. The use of the S-FAST pack also precluded the fighter from transforming into Battroid or Gerwalk mode – the underwing packs had to be jettisoned beforehand. The other standard FAST Pack 2.0 elements could still be carried, though.

 

The modfied Valkyries capable of accepting the S-FAST Pack received an additional “S” to their type designation – more than 100 VF-1s were converted or built in this deep space configuration until late 2011. Initial deployment of the S-FAST Pack was conducted through SVF-24 “Moon Shadows” in early 2010, a unit that was quickly disbanded, though, but re-formed as SVF-124 “Moon Shooters”, tasked with the defense of the lunar Apollo Base and several special missions.

 

After the end of Space War I, the VF-1 continued to be manufactured both in the Sol system and throughout the UNG space colonies. Although the VF-1 would eventually be replaced as the primary Variable Fighter of the U.N. Spacy by the more capable, but also much bigger, VF-4 Lightning III in 2020, a long service record and continued production after the war proved the lasting worth of the design.

 

The VF-1 was without doubt the most recognizable variable fighter of Space War I and was seen as a vibrant symbol of the U.N. Spacy even into the first year of the New Era 0001 in 2013. At the end of 2015 the final rollout of the VF-1 was celebrated at a special ceremony, commemorating this most famous of variable fighters. The VF-1 Valkryie was built from 2006 to 2013 with a total production of 5,459 VF-1 variable fighters with several variants (VF-1A = 5,093, VF-1D = 85, VF-1J = 49, VF-1S = 30, VF-1G = 12, VE-1 = 122, VT-1 = 68)

 

However, the fighter remained active in many second line units and continued to show its worthiness years later, e. g. through Milia Jenius who would use her old VF-1 fighter in defense of the colonization fleet - 35 years after the type's service introduction!

 

General characteristics:

All-environment variable fighter and tactical combat Battroid,

used by U.N. Spacy, U.N. Navy, U.N. Space Air Force

 

Accommodation:

Pilot only in Marty & Beck Mk-7 zero/zero ejection seat

Dimensions:

Fighter Mode:

Length 14.23 meters

Wingspan 14.78 meters (at 20° minimum sweep)

Height 3.84 meters

 

Battroid Mode:

Height 12.68 meters

Width 7.3 meters

Length 4.0 meters

Empty weight: 13.25 metric tons;

Standard T-O mass: 18.5 metric tons;

MTOW: 37.0 metric tons

 

Power Plant:

2x Shinnakasu Heavy Industry/P&W/Roice FF-2001 thermonuclear reaction turbine engines, output 650 MW each, rated at 11,500 kg in standard or in overboost (225.63 kN x 2)

4 x Shinnakasu Heavy Industry NBS-1 high-thrust vernier thrusters (1 x counter reverse vernier thruster nozzle mounted on the side of each leg nacelle/air intake, 1 x wing thruster roll control system on each wingtip);

18 x P&W LHP04 low-thrust vernier thrusters beneath multipurpose hook/handles

 

The S-FAST Pack added 4x P&W+EF-2001 booster thrusters with 120.000 kg each, plus a total of 28x P&W LHP04 low-thrust vernier thrusters

 

Performance:

Battroid Mode: maximum walking speed 160 km/h

Fighter Mode: at 10,000 m Mach 2.71; at 30,000+ m Mach 3.87

g limit: in space +7

Thrust-to-weight ratio: empty 3.47; standard T-O 2.49; maximum T-O 1.24

 

Design Features:

3-mode variable transformation; variable geometry wing; vertical take-off and landing; control-configurable vehicle; single-axis thrust vectoring; three "magic hand" manipulators for maintenance use; retractable canopy shield for Battroid mode and atmospheric reentry; option of GBP-1S system, atmospheric-escape booster, or FAST Pack system

 

Transformation:

Standard time from Fighter to Battroid (automated): under 5 sec.

Min. time from Fighter to Battroid (manual): 0.9 sec.

 

Armament:

2x internal Mauler RÖV-20 anti-aircraft laser cannon, firing 6,000 pulses per minute

1x Howard GU-11 55 mm three-barrel Gatling gun pod with 200 RPG, fired at 1,200 rds/min

 

4x underwing hard points for a wide variety of ordnance, including

12x AMM-1 hybrid guided multipurpose missiles (3/point), or

12x MK-82 LDGB conventional bombs (3/point), or

6x RMS-1 large anti-ship reaction missiles (2/outboard point, 1/inboard point), or

4x UUM-7 micro-missile pods (1/point) each carrying 15 x Bifors HMM-01 micro-missiles,

or a combination of above load-outs

 

The optional Shinnakasu Heavy Industry S-FAST Pack 2.1 augmentative space weapon system added:

6x micro-missiles in two NP-AR-01 micro-missile launcher pods (mounted rear-ward under center ventral section in Fighter mode or on lower arm sections in GERWALK/Battroid mode)

4x12 micro missiles in four HMMP-02 micro-missile launchers, one inside each booster pod

 

The kit and its assembly:

This VF-1 is another contribution to the “Old Kit” Group Build at whatifmodelers.com, running in late 2016. I am not certain about the moulds’ inception date, but since it is an ARII incarnation of this type of kit and even moulded in the early pastel green styrene, I’d think that it was produced in 1982 or 83.

 

Anyway, I love the Macross VF-1, IMHO a design masterpiece created by Shoji Kawamori and one of my favorite mecha designs ever, because it was created as a late 70ies style jet fighter that could transform into a robot in a secondary role. As a simple, purposeful military vehicle. And not like a flashy robot toy.

 

Effectively, this Super Valkyrie is a highly modified OOB kit with many donation parts, and this kit is a bit special, for several reasons. There are several 1:100 OOB kits with FAST Packs from ARII/Bandai available (and still around today), but these are normally only Battroids or Gerwalks with additional parts for the FAST kit conversion. The kit I used here is different: it is, after maybe 25 years of searching and building these kits, the #70 from the original production run. It is (so far!) the only Fighter mode kit with the additional FAST Pack parts! Must be rare, and I have never seen it in catalogues?

 

Until today, I converted my Super or Strike Valkyries from Gerwalk kits, a task that needs some improvisation esp. around the folded arms between the legs, and there’s no OOB option for an extended landing gear. The latter made this Fighter mode kit very attractive, even though the actual kit is pretty disappointing, and AFAIK this kit variant is only available as a VF-1S.

 

With the Super Valkyrie fighter kit you receive basically a Gerwalk with a standard fighter cockpit (which includes a front wheel well and an extended front wheel leg), plus extra parts. The leg/engine-mounted NP-FB-01 systems are less bulbous than the parts on the Gerwalk or Battroid kit, and the OOB dorsally mounted NP-BP-01 boosters are TINY, maybe 1:120 or even 1:144! WTF?

 

Further confusion: the kit includes a set of lower arm parts with integrated rocket launchers, but these are not necessary at all for the Fighter build?! As a kind of compensation there’s a new and exclusive element that simulates the folded arms under the ‘fuselage’ and which, as an added value, properly holds the hand gun under the fuselage. As a quirky flaw, though, the hand gun itself comes in the extended form for the Battroid/Gerwalk mode. For the fighter in flight mode, it has to be modified, but that’s easily done.

 

Anyway, with the potential option to build a Super Valkyrie with an extended landing gear, this was my route to go with this vintage kit. The Super Valkyrie already looks bulky with the FAST Pack added, but then I recently found the S-FAST Pack option with two more boosters under the wings – total overkill, but unique. And I had a spare pair of booster bulks in the stash (w/o their nozzles, though), as well as a complete pair of additional bigger standard FAST boosters that could replace the ridiculous OOB parts…

 

Building such a Super/Strike Valkyrie means building separate components, with a marriage of parts as one of the final steps. Consequently, cockpit, central fuselage with the wings and the air intakes, the folded stabilizer pack, the folded arms element with the handgun, the two legs and the four boosters plus other ordnance had to be built and painted separately.

 

Here and there, details were changed or added, e. g. a different head (a ‘J’ head for the flight leader’s aircraft with two instead of the rare, OOB ‘S’ variant with four laser cannon), covers for the main landing gear (the latter does not come with wells at all, but I did not scratch them since they are hardly recognizable when the kit is sitting on the ground), the typical blade aerials under the cockpit and the feet had to be modified internally to become truly ‘open’ jet exhausts.

 

The wing-mounted boosters received new nozzles and their front end was re-sculpted with 2C putty into a square shape, according to reference sketches. Not 100% exact, but the rest of the VF-1 isn’t either.

 

This VF-1 was also supposed to carry external ordnance and my first choice were four wing-mounted RMS-1 Anti-Ship Reaction Warheads, scratched from four 1.000 lb NATO bombs. But, once finished, I was not happy with them. So I looked for another option, and in a source book I found several laser-guided bombs and missiles, also for orbital use, and from this inspiration comes the final ordnance: four rocket-propelled kinetic impact projectiles. These are actually 1:72 JASDF LGB’s from a Hasegawa weapon set, sans aerodynamic steering surfaces and with rocket boosters added to the tail. Also not perfect, but their white color and sleek shape is a good counterpart to the FAST elements.

 

Experience from many former builds of this mecha kit family helped a lot, since the #70 kit is very basic and nothing really fits well. Even though there are not many major seams or large elements, PSR work was considerable. This is not a pleasant build, rather a fight with a lot of compromises and semi-accuracies.

Seriously, if you want a decent 1:100 VF-1, I’d rather recommend the much more modern WAVE kits (including more realistic proportions).

  

Painting and markings:

The paint scheme for this Super Valkyrie was settled upon before I considered the S-FAST Pack addition: U.N. Spacy’s SVF-124 is authentic, as well as its unique camouflage paint scheme.

The latter is a special scheme for the lunar environment where the unit was originally formed and based, with all-black undersides, a high, wavy waterline and a light grey upper surface, plus some medium grey trim and a few colorful US Navy style markings and codes.

 

My core reference is a ‘naked’ bread-and-butter VF-1A of SVF-124 in Fighter mode, depicted as a profile in a VF-1 source book from SoftBank Publishing. The colors for the FAST Pack elements are guesstimates and personal interpretations, though, since I could not find any reference for their look in this unit.

As a side note, another, later SVF-124 aircraft in a similar design is included as an option in a limited edition 1:72 VF-22S kit from Hasegawa, which is backed by CG pics in a VF-22 source book from Softbank, too.

Furthermore, SVF-124 finds mention in a Japanese modeler magazine, where the aforementioned VF-22S kit was presented in 2008. So there must be something behind the ‘Moon Shooters’ squadron.

 

According to the Hasegawa VF-22S’s painting instructions, the underside becomes black and the upper surfaces are to be painted with FS36270 (with some darker fields on the VF-22, though, similar to the USAF F-15 counter-shaded air superiority scheme, just a tad darker).

Due to the 1:100 scale tininess of my VF-1, I alternatively went for Revell 75 (RAL 7039), which is lighter and also has a brownish hue, so that the resulting aircraft would not look too cold and murky, and not resemble an USAF aircraft.

 

All FAST Pack elements were painted in a uniform dark grey (Humbrol 32), while some subtle decorative trim on the upper surfaces, e.g. the canopy frame, an anti-glare panel and a stripe behind the cockpit and decoration trim on the wings’ upper surfaces, was added with Revell 77 (RAL 7012). Overall, colors are rather dull, but IMHO very effective in the “landscape” this machine is supposed to operate, and the few colorful markings stand out even more!

 

The cockpit interior was painted in a bluish grey, with reddish brown seat cushions (late 70ies style!), and the landing gear became all white. For some added detail I painted the wings’ leading edges in a mustard tone (Humbrol 225, Mid Stone).

 

The kit received some weathering (black ink wash, drybrushing on panels) and extra treatment of the panel lines – even though the FAST Pack elements hide a lot of surface or obscure view.

 

More color and individuality came with the markings. The standard decals like stencils or the U.N. Spacy insignia come from the kit’s and some other VF-1s’ OOB sheets.

Based on the SVF-124 VF-1 profile and taking the basic design a bit further, I used dull red USAF 45° digits for the 2nd flight leader’s “200” modex and the Apollo Base’s code “MA” on the dorsal boosters. Some discreet red trim was also applied to the FAST Packs – but only a little.

 

Since all of SVF-124’s aircraft are rumored to carry personal markings, including nose art and similar decorations, I tried to give this VF-1JS a personal note: the pin-up badges on the dorsal boosters come from a Peddinghouse decal sheet for Allied WWII tanks, placed on a silver roundel base. Unfortunately (and not visible before I applied them) the pin-up decal was not printed on a white basis, so that the contrast on the silver is not very strong, but I left it that way. Additionally, the tagline “You’re a$$ next, Jerry” (which IS printed in opaque white…?) was added next to the artwork – but it’s so tiny that you have to get really close to decipher it at all…

 

Finally, after some soot stains around the exhausts and some vernier nozzels with graphite, the kit received a coat of matt acrylic varnish.

 

Building this vintage VF-1 kit took a while and a lot of effort, but I like the result: with the S-FAST Pack, the elegant VF-1 turned into a massive space fighter hulk! The normal Super Valkyries already look very compact and purposeful, but this here is truly menacing. Especially when standing on its own feet/landing gear, with its nose-down stance and the small, original wheels, this thing reminds of a Space Shuttle that had just landed.

 

Good that I recently built a simple VF-1 fighter as a warm-up session. ARII’s kit #70 is not a pleasant build, rather a fight with the elements and coupled with a lot of compromises – if you want a Super Valkyrie Fighter in 1:100, the much more modern WAVE kit is IMHO the better option (and actually not much more pricey than this vintage collector’s item). But for the vintage feeling, this exotic model kit was just the right ticket, and it turned, despite many weaknesses and rather corny details, into an impressive fighter. Esp. the lunar camouflage scheme looks odd, but very unique and purposeful.

 

Anyway, with so many inherent flaws of the ARII kit, my former method of converting a pure (and much more common) Gerwalk kit into a space-capable VF-1 fighter is not less challenging and complicated than trying to fix this OOB option into a decent model. :-/

Miracle of the eye

ref:

www.miracleintheeye.com/miracle_eye_06.html

 

www.evidencesofcreation.com/index.php

 

www.astrolabe.com/books/array-quran-and-science-and-harun...

 

In order to better understand the perfection of God's creation, look at only a few of the millions of other examples of His art. As it says in Qur'an, all creatures are under His complete control:

 

. There is no creature He does not hold by the forelock. (Qur'an, 11: 56)

 

A countless number of organisms are living on this planet; and millions of different insect species alone.Of all the different types of eye, the human eye is the most superior overall, although the eyes of some species boast of features that are superior to those of humans. There are as many different types of eye as there are species, and we have already shown how impossible it is for such a variety to evolve through mutations and natural selection.

 

God has given every organism an eye that suits their lifestyle and feeding habits. In this section, we'll examine the eye structures of many different species.

 

Insect Eyes

  

Insects view the world through thousands of tiny eyes.

Compared to human eyes, the eyes of insects are considerably different. Their structures come in one of two types, simple or complex.

 

Simple-structured eyes are round and small, capable only of separating light and dark. Compound eyes, on the other hand, are larger and more complex, made up of hundreds of small pieces. Each "piece" is actually a small eye because it contains light sensitivecells, a lens, and connections to the brain.

  

As mentioned before, a human eye's lens can change shape, letting us focus on objects at various distances. The lens in an insect's eye cannot change shape, however, and so insects cannot focus.

 

The compound eye works by each of the eye's six-sided compartments (called ommatidia) detecting a tiny portion of the visual field. The information from each ommatidium is then combined, like pieces of a mosaic, to form a single image of the outside world.

 

The higher the number of ommatidia, the keener the vision becomes, with each unit contributing a different part of the complete picture. 35

 

The head of the common housefly is dominated by a pair of large compound eyes containing approximately 4,000 ommatidia. In wingless insects such as female fireflies there are 300 ommatidia, 5,100 in mayflies, 9,000 in yellow-winged coleopterans and between 10,000 and 28,000 in dragonflies and damselflies.

  

The wide visual perspective of a fly's eyes.

   

A Visual Range of 360 Degrees

 

The housefly's eye contains 4,000 small, simple ommatidia which can be moved at will. Since each ommatidium faces a different direction, the fly is able to see to the front, back, left, right, top and bottom, giving it a 360 degree perspective of the world.

 

Each ommatidium is sensitive to light shining in its direction, and uses its own lens and eight sensitive cells to process it. House flies have a combined total of 48,000 light-sensitive cells, allowing them to see 100 images per second. In this regard, their vision is ten times superior to the human eye. Two-thirds of the fly's brain is devoted purely to sight. The total number of light-sensitive cells means that 48,000 signals are sent here every tenth of a second.

 

Most people think of the fly as one of the most basic forms of life, but its visual system is in fact one of the most complicated we know.

  

Thanks to the flawless design of its eyes, the housefly can look 360 degrees around. At left, a detailed diagram of an ommatidium, of which the fly's eye contains some 4,000.

   

A tiny fly did not evolve or mutate its 4,000 eyes over a period a time. Clearly. This is a special creation. Of course, the fly is not composed of merely its visual system-it also has special digestive, reproductive and flight systems. Only with all its systems intact can the fly thrive. It is not possible for a fly to exist, for example, without a digestive or respiratory system. Nor are there any blind insects flying around! This is solid evidence that the fly was created by God in its current state, as mentioned in the Qur'an:

 

Mankind! An example has been made, so listen to it carefully. Those whom you call upon besides God are not even able to create a single fly, even if they were to join together to do it. And if a fly steals something from them, they cannot get it back. How feeble are both the seeker and the sought! (Qur'an, 22: 73)

 

An Insect with 56,000 Eyes

 

Among all known species, dragonflies have the greatest number of ommatidia. Each eye contains 30,000 of them,36 which can clearly see objects up to 20 feet away.37

 

To recap this phenomenon, a single tiny insect has a total of 56,000 eyes, each of which has a lens, retina, and thousands of nerves connecting it to the central nervous system. As a result of this, the dragonfly can see its prey and understand what it is seeing.

 

The presence of just a single eye with a single neuron and the ability to evaluate a single signal is a miracle on its own. But there are thousands of these eyes, all working in complete harmony. This is just another of God's countless phenomenon. God is the One Who has no equal in creation.

 

Ultraviolet Vision

 

Butterflies and bees both possess a special sense of sight, allowing them to reach sources of food with ease.

 

In some flowers, the pigments form distinct patterns that are invisible to us, but visible to bees and butterflies, who can see ultraviolet light. Called nectar guides, these patterns are like the landing strips of an airport, directing the insects to the nectar within the flower. It is as if their food sources were lit up and signposted especially for them. To our eyes, the coneflower appears to be a uniformly yellowish orange, but to a bee or butterfly, it appears as a corona of yellow with a glowing ultraviolet bull's eye in its center. This pattern guides the bee to where it can collect the nectar or pollen.

 

Bees feed on the pollen produced by plants. The plants, on the other hand, needs the bee to spread their pollen among other flowers of the same species in order to reproduce. Therefore, the flower uses its petals to attract the bee and sticks pollen onto the bee's legs as it feeds. Both partners possess the necessary features to enable this collaboration. Imagine a situation wherein flowers continued to reflect in the ultraviolet range, but bees were unable to see that portion of the spectrum. Both species would swiftly go extinct, because the bee would not be able to feed, nor the flower to reproduce. This is proof that these co-dependent organisms were created by the same Creator.

 

Birds

 

For a flying creature, the most important sense is sight, because the miracle of flight would become a very dangerous affair without the

 

ability to see. Birds, therefore, have been blessed by God with a superior sense of sight, in addition to the ability to fly.

 

A bird's sense of sight has a wider perspective and can operate much more quickly than a human's can. An object or view that we humans have to regard at length, a bird can see as a whole, in one quick glance.

 

Eyes are crucial for the predator owl, which can see ten times more powerfully than humans at night.38

 

Unlike a human, a bird cannot move its eyes in their sockets. But birds can quickly move their heads and necks around to expand their perspective. Without moving its head, an owl has an 80-degree field of vision. But some species of owl can rotate their heads to up to 360 degrees-a full circle!

 

The visual field of one human eye is 150 degrees laterally, and only 180 degrees binocularly, or a half circle.39

 

As mentioned already, predators such as the owl have very keen night vision, often six times greater than that of humans. This allows them to perform precisely accurate hunting maneuvers.

 

Larger eyes contain more visual cells, providing better vision. A predator bird can have more than a million visual cells in each of its eyes.

 

At night, owls and similar nocturnal birds can see much better than other species. Looking for food, these predator birds search for small animals on the ground, and their eyes can pick up the slightest movements, thanks to a high number of light-sensitive rods in their retinas. As we explained, the more rod cells, the keener night vision becomes. But for this vision, predator birds do pay a price: They sacrifice the sense of color. They see the world in black and white but, owing to their lifestyle, they do not need to see color. So cone cells are quite fewer in the eyes of nocturnal birds.

 

During the past minute, as you read this book, you blinked 22 times. That's how your eyes maintained their moisture and cleanliness. But for that split-second that you blinked, your eyes stopped doing their job. For the relatively sedate lifestyle of a human, this may not be a problem. But for a bird in flight, that split-second may be critical.

 

This is why birds have a third eyelid-a transparent layer that blinks and cleans-without their having to close their outer eyelids. This lid sweeps sideways across the eyeball, starting from the side nearest the beak. For birds that dive underwater, it also acts as goggles, protecting the eye from harm. In a sense, birds have been equipped with goggles and aviator glasses from birth.

 

Although nocturnal birds cannot see color, some smaller birds feed on seeds and insects, and therefore do need to discern colors. The eyes of these smaller birds are placed on either side of the head, which lets them see a wide area with minimal movement of the head and neck.

 

The umbrella birds, also known as black herons, encounter a number of difficulties when they hunt in water. As is well-known, most light reflects off the water-which has a negative effect on the bird's ability to see objects under the water's surface. The black heron solves this problem by spreading its wings. This cuts the sunlight and any reflections, allowing it to see more clearly and hunt for fish underwater.

 

If the black heron didn't use its wings this way, it would be unable to see its food and therefore starve. But seabirds are somehow born knowing the laws of optics, and take the needed precautions accordingly. Could it be that all the seabirds came together to find a practical solution to their problem? Or did they take a mass physics lesson and arrive at a solution by experimenting?

 

Hunting Eyes

 

Eagles fly at an altitude of thousands of meters, in a manner similar to modern war planes, yet are able to comb the landscape below in staggering detail. The eagle can detect even the slightest of movements or color changes while in flight. It owes this ability to a very special eye structure.

  

In humans, the portion of the retina with the most acute vision is the fovea centralis, which has the highest concentration of cone cells. Eagles have two foveae, giving them an incredibly sharp sense of sight. Humans have only one fovea in each eye-for binocular, or forward vision. When we look at an object, both our eyes are directed toward the object. This allows our brain to merge both the images to create a sense of depth. The eagle contains a binocular fovea like ours, but also has a fovea for monocular vision that allows each eye to look sideways and see a separate image. So eagles can see both forward and to the side at the same time.40

 

The eagle has a visual perspective of some 300 degrees, as well as an extra focusing power. Humans change the shape of their lenses to focus. But an eagle can change the shape of both lens and cornea. This gives it extra focusing power.41 It can also scan a 30,000 hectare (116 square miles) field from an altitude of 4,500 meters (14,700 feet), or spot a camouflaged rabbit from 90 meters (300 feet) with ease.42

 

To attain this super-sharp vision, an eagle's retinal cells are tinted with special colored oil droplets, increasing the contrast for objects seen against the blue sky or green forest. Thanks to this, the eagle can spot minute changes in contrast from thousands of meters above and swoop down to hunt. The fact that a mere drop of oil makes this possible is doubtlessly one of God's countless blessings.

 

Flying is a miracle in itself. If one aspect of the present structure or position of a bird's wing were changed, it would be unable to fly. Therefore, it isn't possible for wings to have evolved over time.

  

As mentioned before, something else that couldn't possibly have evolved is the visual system. This is reinforced by the flawless nature of an eagle's eye. An eye with two foveae cannot form over time, as a result of coincidences. That second fovea was deliberately created to answer the bird's needs.

 

For an eagle, that droplet of oil in its retina cells is of staggering importance... But who made this fine optical adjustment? Did the eagle add

 

the oil himself, or on other animals' recommendation? Of course not. The eagles have enjoyed this feature from birth, for thousands of years.

 

So why are our eyes not as sharp as an eagle's? If human eyes contained the same features, they'd each be the size of a grapefruit. Moreover, humans don't need to spot a camouflaged rabbit from a kilometer away. This is why God gave humans their present eyes in a most aesthetic form.

 

Jumping Spiders

 

Compared to ordinary spiders, the jumping spider leads a very unusual life. Rather than make a web and wait for a catch, these spiders hunt their prey instead. This is why-unlike ordinary spiders, which are almost blind-they have exceptionally acute vision.

  

A jumping spider hunts by securing itself to the branch of a tree with the thread it secretes. Then it throws itself toward an insect flying nearby, catching it in midair. In order to snare its catch, the spider needs to see its prey, and determine the direction and speed at which the target is traveling. Also, of course, it must determine its own speed and the duration of the leap. In order to do all this, the spider needs not only an advanced visual system, but an information processing center to make all the necessary calculations.

 

Jumping spiders have four pairs of eyes, for a total of eight. The front two are the most impressive, perhaps the best eyes one can find in any arthropod. The retina inside the eye can move in three dimensions, enabling the spider to look in all directions and focus on its subject. The other six eyes are positioned around the head, affording 360-degree vision.43

 

The jumping spider's visual acuity is actually very similar to our own, such that they even perceive images on a television screen. When most animals look at a television, they see only a series of moving dots. But research has indicated that jumping spiders respond to televised pictures of other spiders and insects.

 

The jumping spider's visual system is highly complex and, in some respects, surpasses even a human's. A tiny spider can look in different directions, detect motions, and estimate speed and distance. Of course, the spider never asked for these abilities, nor did it develop them on its own, over time. Everything the spider possesses was given to him by God.

 

The Protection of Animal Eyes

 

As the body's most sensitive organs, the eyes must therefore be well protected. This is why animal skulls have been constructed in such a way as to provide their eyes with maximum protection.

 

In animals like cats and dogs, the majority of the eye lies inside the skull, with only a small portion protruding outside. The bones surrounding the eye effectively act as a shield against impacts, and the eyelids help protect against direct injury.

 

The eyes of a camel-a mammal that lives under incredibly harsh conditions-are provided with the protection they need. The bone structure around its eye not only protects it from impacts, but also from harsh sunrays. Not even violent sandstorms can harm a camel's eyes, thanks to its eyelashes, which are long and intertwined, preventing any dust from entering.

 

Eyes in the Sea

 

There are considerable differences between land and underwater creatures, because under the surface is effectively another world, whose inhabitants have been modeled to best suit their environment. But just because they spend their lives underwater doesn't mean that their basic requirements are any different from ours. To stay alive, they still need to breathe, feed and avoid being hunted. They have to be able to see the world around them, so that they can distinguish between prey and foe-and require special eyes that let them see clearly underwater.

 

Fish view their world through a transparent layer that covers their eyes, similar in principle to the goggles worn by human divers. But be it a whale or a herring, an underwater creature's field of vision is restricted. Deeper than 30 meters (99 feet) below the surface, distant vision becomes unnecessary. Most of the time, in fact, fish need to see only those objects directly in front of them, and their eyes are created to meet this need. Their rigid, globular lens is particularly adapted for seeing close objects. But when they do need to see at a distance, a set of special muscles pulls the entire lens back toward the retina.44

 

The spherical lens in a fish's eye works well underwater. Because of the higher degree of refraction (the bending of light) in water than in air, a fish's lens has to be much more curved than a human's. To produce a clear image, the lens bends the light a lot more than does a flatter one-such as those in humans and other land animals.45

 

Water creatures are always in danger of becoming food for larger creatures. But they do have a special defense mechanism not seen in mammals: Fish can perceive more than one image at the same time.

 

A fish's eyes are placed on either side of its head. The image seen by each eye is recorded in the opposite half of its brain. But since the image is viewed by one eye only, it is two-dimensional, which prevents the fish from judging distances. This is why, when it spots some potential threat, both eyes focus in the same direction to judge the distance. Straight ahead, the visual arcs of the two eyes overlap to provide a narrow band, where the fish enjoys binocular vision.

 

With the exception of a few species, fish cannot see in color. They have no need to, because only a few meters underwater, most colors are absorbed and disappear. A fish's entire world is mostly shades of blue and green.

 

Fish are more sensitive than land animals to dim light, because their retinas contain a higher number of cells sensitive to low intensities, letting them make use of every amount of light possible.

 

Sea turtles generally feed on fish. In the process, they also consume a large quantity of sea salt, which could be unhealthy if they digested it. Rather then simply eject salt from the body, the turtle transfers it to special sacs located on to the side of its eyes. Here, the salt is cleverly recycled and used to produce tears.46

 

Octopus Eyes

 

Of all the invertebrates, the octopus has one of the most complex eye structures. As in vertebrates, each of the octopus's two large, complex eyes is like a camera, in structure, and the creature's vision is acute.

     

The octopus eye and the vertebrate eye are extraordinarily similar. Each includes a cornea, an iris, an accommodating lens, a fluid-filled vitreous humor, and a retina. However, there are major differences. For instance, octopi change their range of focus by moving the entire lens closer or farther away from the retina, whereas we change the shape of our cellular lens in order to bring objects into focus.

 

As mentioned earlier, one of the biggest struggles for evolutionists was in forming some explanation of how octopus eyes originated. According to evolutionary theory, octopi (which are invertebrates) and men (vertebrates) developed completely independently of each other, over time. And yet both man and octopus have equally well-developed visual systems, with similar structures performing similar functions.

 

But if the two species developed separately, why are their eyes so similar? It seems that the impossible has taken place not just once, but at several times and in several places. If the human eye is the product of coincidences and not creation, then shouldn't it be considerably different than the octopus's eye? The theory of evolution simply cannot answer thousands of basic questions like this.

 

The Archer Fish

 

Archer fish hunt by firing mouthfuls of water at nearby insects. Their superior sense of sight allows them to make acute geometric calculations from underwater so as to estimate the correct location of the prey in the outside air. They never miss their targets. This intelligent behavior surely is not the work of the fish itself. It is God Who inspires the Archer fish and all other creatures how to act.

    

This fish is famous for being a living water pistol-filling its mouth with water and squirting it at insects resting on branches or twigs above the water. The element of surprise causes the insect to lose its grip and plunge into the water, where it becomes an easy catch.

 

What's remarkable about the process is that even as the archer fish prepares itself, it doesn't raise its head out of the water. While still submerged, it can accurately determine the insect's location. But the apparent position of objects outside the water is distorted by the retraction of light. For example, if you wanted to shoot an arrow from beneath a swimming pool at a point in the air outside, you'd have to know at what angle light retracts upon the water and adjust your aim accordingly.

 

But this fish seems to overcome this problem and shoots on target every time. It is able to hit a tiny insect with no difficulty.47 All archer fish possess this ability, but not through lessons and physical calculations. It is God Who inspires this creature.

 

The Crab's Periscope

 

A crab has two eyes on the ends of stalks. These act like little periscopes, allowing the crab to see what's going on above, even if it is hiding beneath the sand. At any sign of danger, the stalks can be lowered for protection into sockets on the carapace.

         

REPTILE EYES

 

Most reptiles can see a large array of colors, allowing them to pick out even the most effectively camouflaged insects. This gives them a major hunting advantage.

 

Chameleons feed on insects, and their hunting tactics are most unusual because their eyes play a greater role than usual. Chameleons can move each eye independently of the other, allowing them scout the surroundings and watch their insect prey at the same time, as they edge closer to their objective.48 When it is close enough, a chameleon turns both eyes upon its prey, determines its position, and then shoots out its long sticky tongue to catch the meal.

 

Double Vision

 

On most species of snakes, the eyes are placed on either side of the head, which produces two different images in the snake's brain.

 

However, this location of the eyes doesn't stop the snake from seeing forward. In fact, this positioning gives the snake a wide visual perspective, allowing it to look forwards, backwards and upwards with ease.

 

Infrared Vision

 

As you've seen, the human eye can perceive only a specific range of wavelengths of light. Some species of snake are capable of seeing greater wavelengths than humans, including infrared light, which humans can sense only as heat.

 

Snakes have small pit organs that can visually register infrared radiation. These organs are a hundred thousand times more sensitive to infrared than human skin and can detect even the slightest change in a body's temperature.

 

For example, the rattlesnake can locate a warm-blooded animal or human even in pitch darkness, because such creatures radiate off heat waves that the snake can detect-an incredible advantage for any creature hunting at night.

 

The principle of detecting objects and soldiers by the heat they emit is also used in recent optical military equipment. It took years of research to develop the technology behind this kind of equipment, but snakes enjoy the same ability from the moment they hatch from their eggs. It took decades for humans to develop heat-sensing equipment, but snakes have always had it.

 

Eyelids

 

There are vast differences between a reptile's eyelids and the eyelids of other creatures. It may appear as if snakes do not have eyelids, for example, but their eyes are in fact covered by an immobile, transparent layer of scales.

 

Lizards, on the other hand, have movable eyelids. But in the desert lizard especially, the eyelids are upturned. This keeps out the sand, preventing it from harming the eye when the lizard buries itself in the sand.

   

The Sensitive Eyes of a Frog

 

Recent research has revealed some of the frog's eye's interesting abilities. One kind of retinal cell responds strongly to small, dark, round moving objects and is most active when those objects moved irregularly. It is as if the neurons of the frog eyes were designed especially to detect flies. Some scientists call their eyes "bug detectors."49

   

Cats' Eyes

 

The eye of a cat contains a layer called the tapetum lucidum, not found in humans. Positioned immediately behind the retina, it reflects incoming light, doubling the amount of light the eye can use and allowing cats to see in much dimmer light than we can.

 

This layer is also the reason why cat eyes seem to glow when a flashlight beam is shined directly at them.

 

Cat eyelids are prized wide open at night, allowing as much light as possible to enter. Another reason why cats can see so well in the dark is because their retinas contain more rod cells than cone cells. Thanks to this system created by God, wild cats can comfortably hunt at night.

  

A large multi-role cargo vessel, capable of carrying a mix of containerized, outsized, liquid, and small package cargo. Its distinctive hammerhead forward structure served as debris shielding for containers mounted to its forward truss, though the gradual improvement of energy shielding rendered this obsolete shortly after introduction. Some derivatives removed it, others retained the shield and extended it aftwards to form a pressurized section for passenger transport

Detail info Natural Ingredients Capable of Delaying Aging at hormigonpulido.org/1107/natural-ingredients-capable-of-de... by health post

+++ DISCLAIMER +++

Nothing you see here is real, even though the conversion or the presented background story might be based on historical facts. BEWARE!

  

Some background:

The Indian „Samudree Baaj“ (समुद्री बाज, Sea Hawk) was a highly modified, navalized version of the British BAE Systems Hawk land-based training jet aircraft, which had been manufactured under license by Hindustan Aeronautics Limited (HAL). The first indigenously built Hawk Mk. 132 trainer was delivered in 2008 to the Indian Air Force, and the type has since then been updated with indigenous avionics into the “Hawk-I” Mk. 132 from 2020 onwards. The aircraft’s Rolls Royce Adour Mk 871 engine was also license-built by HAL, and the company had experience from a wide range of aircraft projects in the past.

 

The Samudree Baaj project was initiated in 2006 by the Indian Navy, as part of the long historic plan to provide the Indian Navy with a fully capable aircraft carrier. This plan had been initiated in 1989, when India announced a plan to replace its ageing British-built aircraft carriers, INS Vikrant and INS Viraat (ex-HMS Hermes), with two new 28,000-ton Air Defence Ships (ADS) that would operate the BAe Sea Harrier aircraft. The first vessel was to replace Vikrant, which was set to decommission in early 1997. Construction of the ADS was to start at the Cochin Shipyard (CSL) in 1993 after the Indian Naval Design Organisation had translated this design study into a production model. Following the 1991 economic crisis, the plans for construction of the vessels were put on hold indefinitely.

 

In 1999, then-Defence Minister George Fernandes revived the project and sanctioned the construction of the Project “71 ADS”. By that time, given the ageing Sea Harrier fleet, the letter of intent called for a carrier that would carry more modern jet fighters. In 2001, CSL released a graphic illustration showing a 32,000-ton STOBAR (Short Take-Off But Arrested Recovery) design with a pronounced ski jump. The aircraft carrier project finally received formal government approval in January 2003. By then, design updates called for a 37,500-ton carrier to operate the MiG-29K. India opted for a three-carrier fleet consisting of one carrier battle group stationed on each seaboard, and a third carrier held in reserve, in order to continuously protect both its flanks, to protect economic interests and mercantile traffic, and to provide humanitarian platforms in times of disasters, since a carrier can provide a self-generating supply of fresh water, medical assistance or engineering expertise to populations in need for assistance.

 

In August 2006, then-Chief of the Naval Staff, Admiral Arun Prakash stated that the designation for the vessel had been changed from Air Defence Ship (ADS) to Indigenous Aircraft Carrier (IAC). The euphemistic ADS had been adopted in planning stages to ward off concerns about a naval build-up. Final revisions to the design increased the displacement of the carrier from 37,500 tons to over 40,000 tons. The length of the ship also increased from 252 metres (827 ft) to 262 metres (860 ft).

It was at this time that, beyond the MiG-29K, primarily a carrier-capable trainer and also a light (and less costly) strike aircraft would be needed. With the running production of the Hawk Mk. 132 for the Indian Air Force and BAE Systems’ connection and experience to the USA and McDonnell/Boeing’s adaptation of the Hawk as the US Navy’s carrier-capable T-45 trainer, HAL was instructed to develop a suitable aircraft family on the Hawk’s basis for the new carriers.

 

HAL’s Samudree Baaj is a fully carrier-capable version of the British Aerospace Hawk Mk. The Hawk had not originally been designed to perform carrier operations, so that numerous modifications were required, such as the extensive strengthening of the airframe to withstand the excessive forces imposed by the stresses involved in catapult launches and high sink-rate landings, both scenarios being routine in aircraft carrier operations.

 

The aerodynamic changes of the aircraft, which were mutually developed by HAL and BAE Systems, included improvements to the low-speed handling characteristics and a reduction in the approach speed. Most notable amongst the changes made to the Hawk's design were extended flaps for better low-speed handling, along with the addition of spoilers on the wings to reduce lift and strakes on the fuselage which improved airflow and stabilizer efficiency.

Other, less obvious modifications included a reinforced airframe, the adoption of a more robust and widened landing gear, complete with a catapult tow bar attachment to the oleo strut of the new two-wheel nose gear design, and an arresting hook. The tail fin was extended by 1 foot (12 in, 30.5 cm) to compensate for the loss of the Hawk’s ventral stabilizing strakes. To make room for the arrester hook, the original ventral air brake was split and re-located to the flanks, similar to the USN’s T-45 trainer.

 

At the time of the Samudree Baaj’s design, the exact catapult arrangement and capacity on board of India’s new carriers was not clear yet – even more so, since the MiG-29K and its powerful engines might have made a catapult obsolete. Therefore, the Samudree Baaj was designed to be operable either with a ski jump ramp (in the style of the Russian Kiev class carriers, of which India had purchased one as INS Vikramaditya) or with only minimal launch support within the projected STOBAR concept, which included a relatively short-stroke steam catapult and a similarly short, undampened arrester gear.

 

By 2009 the basic airframe had been defined and four prototypes were built for two versions: the Mk. 101 trainer, which was basically a navalized version of the land-based Mk. 132 with almost the same mission equipment, and the Mk. 201, a single-seater. Two airframes of each type were built and the first Samudree Baaj flight took place in early 2011. The Indian government ordered 30 trainers and 15 attack aircraft, to be delivered with the first new Indian carrier, INS Vikrant, in late 2017.

 

The Samudree Baaj Mk. 201 was developed from the basic navalized Hawk airframe as a light multirole fighter with a small visual signature and high maneuverability, but high combat efficiency and capable of both strike and point defense missions. It differed from the trainer through a completely new forward fuselage whereby the forward cockpit area, which normally housed the trainee, was replaced by an electronics bay for avionics and onboard systems, including a fire control computer, a LINS 300 ring laser gyroscope inertial navigation system and a lightweight (145 kg) multimode, coherent, pulse-Doppler I band airborne radar. This multimode radar was developed from the Ferranti Blue Fox radar and capable of airborne interception and air-to-surface strike roles over water and land, with look-down/shoot-down and look-up modes. It had ten air-to-surface and ten air-to-ground modes for navigation and weapon aiming purposes.

A ventral fairing behind the radome carried a laser rangefinder and a forward-looking infrared (FLIR). Mid-air refueling was also possible, through a detachable (but fixed) probe. GPS navigation or modern night-flight systems were integrated, too.

 

Like the trainer, the Mk. 201 had a total of seven weapon hardpoints (1 ventral, four underwing and a pair of wing tip launch rails), but the more sophisticated avionics suite allowed a wider range of ordnance to be carried and deployed, which included radar-guided AAMs for BVR strokes and smart weapons and guided missiles – especially the Sea Eagle and AGM-84 “Harpoon” anti-ship missiles in the Indian Navy’s arsenal. For the maritime strike role and as a support for ASW missions, the Samudree Baaj Mk. 201 could even deploy Sting Ray homing torpedoes.

Furthermore, a pair of 30mm (1.18 in) ADEN machine cannon with 150 RPG were housed in a shallow fairing under the cockpit. The self-protection systems include a BAE SkyGuardian 200 RWR and automatic Vinten chaff/flare dispensers located above the engine exhaust.

 

The Samudree Baaj project was highly ambitious, so that it does not wonder that there were many delays and teething troubles. Beyond the complex avionics integration this included the maritime adaptation of the Adour engine, which eventually led to the uprated Adour Mk. 871-1N, which, as a side benefit, also offered about 10% more power.

However, in parallel, INS Vikrant also ran into delays: In July 2012, The Times of India reported that construction of Vikrant has been delayed by three years, and the ship would be ready for commissioning by 2018. Later, in November 2012, Indian English-language news channel NDTV reported that cost of the aircraft carrier had increased, and the delivery has been delayed by at least five years and is expected to be with the Indian Navy only after 2018 as against the scheduled date of delivery of 2014. Work then commenced for the next stage of construction, which included the installation of the integrated propulsion system, the superstructure, the upper decks, the cabling, sensors and weapons. Vikrant was eventually undocked on 10 June 2015 after the completion of structural work. Cabling, piping, heat and ventilation works were to be completed by 2017; sea trials would begin thereafter. In December 2019, it was reported that the engines on board the ship were switched on and in November 2020, only the basin trials of the aircraft carrier were completed.

 

By that time, the first Samudree Baaj aircraft had been delivered to Indian Navy 300 squadron, and even though only based at land at Hansa Air Station, flight training and military operations commenced. In the meantime, the start of Vikrant's trials had initially been scheduled to begin on 12 March 2020, but further construction delays caused that to be moved back to April. With the COVID-19 crisis, the navy explained that trials were unlikely to begin before September/October. During the Navy Day press meeting in December 2019, Navy Chief Admiral Karambir Singh said Vikrant would be fully operational before the end of 2022. The COVID-19 pandemic had already pushed that back to 2023 and further delays appeared possible.

In late 2020, the Indian Navy expected to commission Vikrant by the end of 2021. Until then, the Samudree Baaj fleet will remain land-based at INS Hansa near Goa. This not only is the INAS 300 home base, it is also the location of the Indian Navy's Shore Based Test Facility (SBTF), which is a mock-up of the 283-metre (928 ft) INS Vikramaditya (a modified Kiev-class aircraft carrier) deck built to train and certify navy pilots, primarily the the Mikoyan MiG-29K for operating from the aircraft carrier, but now also for the Samudree Baaj and for the developmental trials of the naval HAL Tejas lightweight fighter.

  

General characteristics:

Crew: 1

Length: 11.38 m (37 ft 4 in)

Wingspan: 9.39 m (30 ft 10 in)

Height: 4.30 m (14 ft 1 in)

Wing area: 17.66 m2 (190.1 sq ft)

Empty weight: 9,394 lb (4,261 kg)

Gross weight: 12,750 lb (5,783 kg)

Max takeoff weight: 9,101 kg (20,064 lb)

Fuel capacity: 1,360 kg (3,000 lb) internal

3,210 kg (7,080 lb) with 3 drop tanks

Powerplant:

1× Rolls-Royce Turbomeca Adour Mk. 871-1N non-afterburning turbofan, 28,89 kN (6,445 lbf) thrust

 

Performance:

Maximum speed: 1,037 km/h (644 mph, 560 kn) at sea level

Maximum speed: Mach 1.2 (never exceed at altitude)

Cruise speed: 796 km/h (495 mph, 430 kn) at 12,500 m (41,000 ft)

Carrier launch speed: 121 kn (139 mph; 224 km/h)

Approach speed: 125 kn (144 mph; 232 km/h)

Never exceed speed: 575 kn (662 mph, 1,065 km/h) / M1.04 design dive limit

Stall speed: 197 km/h (122 mph, 106 kn) flaps down

Range: 892 km (554 mi, 482 nmi) internal fuel only

Combat range: 617 km (383 mi, 333 nmi) with 2x AGM-84 and 2x 592 l (156 US gal; 130 imp gal)

Ferry range: 1,950 km (1,210 mi, 1,050 nmi) with 3 drop tanks

Service ceiling: 15,250 m (50,030 ft)

G-limits: +8/-3

Rate of climb: 58.466 m/s (11,509.1 ft/min)

Takeoff distance with maximum weapon load: 2,134 m (7,001 ft)

Landing distance at maximum landing weight with brake chute: 854 m (2,802 ft)

Landing distance at maximum landing weight without brake chute: 1,250 m (4,100 ft)

 

Armament:

2× 30 mm (1.181 in) Aden cannon with 150 rounds each

7× hardpoints (4× under-wing, 1× under-fuselage and 2 × wingtip)

for a total ordnance of 3.085 kg (6,800 lb) and a wide range of weapons

  

The kit and its assembly:

A subtle kitbashing project, inspired by a CG-rendition of a carrier-based (yet un-navalized) BAe Hawk 200 in Indian Navy service by fellow user SPINNERS in January 2021. I found the idea inspiring but thought that the basic concept could be taken further and into hardware form with a model. And I had a Matchbox Hawk 200 in The Stash™, as well as a McDonnell T-45 trainer from Italeri…

 

The plan sounds simple: take a T-45 and replace the cockpit section with the single-seat cockpit from the Hawk 200. And while the necessary cuts were easy to make, reality rears its ugly head when you try to mate parts from basically the same aircraft but from models by different manufacturers.

 

The challenges started with the fact that the fuselage shapes of both models differ – the Matchbox kit is more “voluminous”, and the different canopy shape called for a partial spine transplant, which turned out to be of very different shape than the T-45’s respective section! Lots of PSR…

In order to improve the pretty basic Matchbox Hawk cockpit I integrated the cockpit tub from the Italeri T-45, including the ejection seat, dashboard and its top cover.

For the totally different T-45 front wheel I had to enlarge the respective well and added a “ceiling” to it, since the strut had to be attached somewhere. The Hawk 200’s ventral tub for the cannons (which only the first prototype carried, later production aircraft did not feature them) were retained – partly because of their “whiffy“ nature, but also because making it disappear would have involved more major surgeries.

Most of the are behind the cockpit comes from the Italeri T-45, I just added a RHAWS fairing to the fin, extending it by 3mm.

 

A major problem became the air intakes, because the two kits differ in their construction. I wanted to use the Italeri parts, because they match the fairings on the fuselage flanks well and are better detailed than the Matchbox parts. But the boundary layer spacers between intakes and fuselage are molded into the Italeri parts, while the Matchbox kit has them molded into the fuselage. This called for major surgery and eventually worked out fine, and more PSR blended the rest of the fuselage donors around the cockpit together. A tedious process, though.

 

The pylons were puzzled together, including a former Matchbox EA-6B wing pylon under the fuselage, cut down and mounted in reverse and upside down! The ordnance comes from the Italeri NATO weapons set (Matra Magic and AGM-84), the ventral drop tank comes IIRC from an Eduard L-39 Albatros. Matra Magics were chosen because India never operated any Sidewinder AAM, just French or Soviet/Russian missiles like the R-60 or R-73 (unlikely on the Hawk, IMHO), and I had preferred a pair of Sea Eagle ASMs (from a Hasegawa Sea Harrier kit), but their span turned out to be too large for the Hawk’s low wings. The alternative, more slender Harpoons are plausible, though, since they are actually part of the Indian Navy’s inventory.

  

Painting and markings:

The Indian Navy theme was already settled, and I wanted to stay close to SPINNERS’ illustration as well as to real world Indian Navy aircraft. SPINNERS’ Hawk carried the typical Sea Harreir scheme in Extra Dark Sea Grey and White, and I found this livery to look a bit too much retro, because I’d place this what-if aircraft in the early 2020s, when the Sea Harriers had already been phased out. A “realistic” livery might have been an overall mid-grey paint scheme (like the land-based Indian Hawk 132s), but I found this to look too boring. As a compromise, I gave the Samudree Baaj a simple two-tone paint scheme, carried by a few late Indian Sea Harriers. It consists of upper surfaces in Dark Sea Grey (Humbrol 164) and undersides in Medium Sea Grey (Modelmaster 2058), with a low waterline. The Modelmaster MSG has – for my taste – a rather bluish hue and appears almost like PRU Blue, but I left it that way.

 

The decals were puzzled together from variosu sources. the roundels come from a MiG-21F (Begemot), the unit markings and tactical codes from a Model Alliance Sea Harrier sheet, and the stencils are a mix from the Matchbox Hawk 200 and the Italeri T-45.

 

The kit was sealed with matt acrylic varnish from Italeri.

 

The fictional HAL „Samudree Baaj“ looks simple, but combining kits of the basically same aircraft from different manufacturers reveals their differences, and they are not to be underestimated! However, I like the result of a navalized Hawk single-seater, and - also with the relatively simple and dull livery - it looks pretty convincing.

Many thanks to SPINNERS for the creative inspiration - even though my build is not a 100% "copy" of the artwork, but rather a step further into the navalisation idea with the T-45 parts.

 

Not feeling photographically capable these days, even with my new camera. I've also been cleaning out the archives and will probably be posting a lot less in the upcoming months, at least until the weather breaks.

"Love is the only force capable of transforming an enemy into friend." Martin Luther King, Jr.

Rose chafers are capable of very fast flight, flying with their wing cases down like bumble bees. The adult beetles are active between April and September. The beetles fly clumsily and are typically seen in sunny weather.

Rose Chafer~Cetonia aurata

Fantastic solution for those size queens that need the extra length occasionally. This one has a one, and a two, and a three removable leafs allowing it to adjust to your needs.

Capable of crossing the Atlantic in under three hours, Concorde cruised at over twice the speed of sound and reached an altitude of 60,000ft. Her passengers would marvel at the curvature of the Earth and look up at a blue-black sky, as they travelled at 1320mph and sipped Champagne on the edge of space.

I aspire to become a photographer, it runs like a passion in my heart.

 

Life has never been simple and straight to me .. it has always been full of challenges and twist.

 

Until time puts us on a test one never knows what one is capable of ..

 

Its been 8 years I lost my dad suddenly in an accident .. Dad had been my hero and one the best .. he always made me proud to b his daughter and he taught me to fear nothing.

 

My mom who has always been a person who told me that everything in this world is possible.

Her sparkling eyes always told me that to live one has to always think positive.

 

My life took a sudden turn when my dad expired. Though the time was moving but my entire being came to a sudden halt.

 

But God gave me all the strength to stand on and take care of my mom who was suffering from arthritis.

I took a BPO job to sustain but in this rush many a times i felt lost in the crowd.

 

I feel each and everyone of us face difficult situations but i feel more than the situation its very important how we react to that situation.

 

My Mom was to get operated and i lost my job due to recession but my mom courageously said that we will manage .. u don't worry.

 

If one keeps fighting one never die .. one moves in like a river finding ways towards realising dreams.

 

In all this rush I never let my dream and aspiration to fade away .. I kept them strong and alive in my heart .. carrying a dream and responsibility together taught me about life and made me a strong woman.

 

Today I do have my passion in my hand and vision in my eyes to be a best human and have a sparkling soul within.

 

I feel happiness us within you not outside as life goes by .. you start speaking to yourself, you understand what you really need and everyday gets you closer to your dreams .. after a dark night day has to come because every dark cloud has a silver lining so I feel we all should never let go … do not put sword down .. that sword is ‘hope’ within your eyes and pride to carry yourself through every tough situation.

 

Jiye bina gam ke to kya jiye, aur wo khushi ka maza he kya, jo gam ke raaste na guzra ho.

 

Everything can’t be the way you planned but still moving on with your aspirations is rhythm of life.

 

Junoon ke bina hum sirf zinda hai, par hamen jeena chahiye, sirf zinda rahna kaafi nahi.

 

www.humansofmumbai.in

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