External Penetration Testing at Avyaan

The UAE is in the midst of a crisis the likes of which have been unknown to the region until some of its cities opens its gates to foreign wealth.

 

How does the G20 compare with their debt.

 

Full article: www.fsteurope.com/news/global-national-debt/

The Copse External

External view-artist impression

A shot from the photocall for Pardon/In Cuffs which is at the Traverse Theatre this Edinburgh Fringe.

 

Valentijn Dhaenens devised the concept and directs.

 

The performers are: Valentijn Dhaenens; Clara Van Der Broek; and Korneel Hamers.

 

You can find out more about the play and buy tickets, here: www.traverse.co.uk/whats-on/event-detail/617/pardon--in-c...

Campus Photography 2019

This table is hinged on the right, locks on the left. Unlock and swing from 90 to 180 degrees, drop the adjustable legs, then open the hatch.

The Pyramid of Unas dates back to the end of the 5th Dynasty (24th century BC) and whilst its external appearance has been reduced to a large ruined mound its internal chambers remain intact and are decorated with hieroglyphic texts, the first used in any tomb, giving spells and incantations to assist the journey of the deceased's soul in the afterlife.

en.wikipedia.org/wiki/Pyramid_of_Unas

 

Saqqara, the necropolis of Memphis, is one of the most fascinating sites in Egypt, as well as one of its earliest. The major monument here is Djoser's step pyramid, the earliest stone-built architectural monument which dominates the site.

 

Other pharaohs built pyramids here though most have not survived in such good conditions and some were never even finished. Two of the pyramids (those of Unas and Teti) contain chambers decorated with hieroglyph texts (the so called 'Pyramid Texts') that are amongst the earliest manifestations of ancient Egyptian writing.

 

The most significant survival from an artistic point of view however are the many early mastaba tombs (built from mud-brick and adorned with fine limestone reliefs within). Most visitors will not have time to do them justice and may have to just choose a couple to focus on if making a first visit. The art is of a very high quality and quite remote stylistically from the more esoteric scenes within the much later tombs of Thebes.

 

Saqqara can be a bewildering site to explore at first, but a little prior research will reveal the locations and best places to visit.

en.wikipedia.org/wiki/Saqqara

A cute little pigeon perched on the external metal structure outside the back of my office.

 

The title comes from the catch cry of the protagonist in a cartoon called "Pigeon Boy".

Yuri Alekseyevich Gagarin [nb 1] (9 March 1934 – 27 March 1968) was a Soviet Air Forces pilot and cosmonaut who became the first human to journey into outer space, achieving a major milestone in the Space Race; his capsule Vostok 1 completed one orbit of Earth on 12 April 1961. Gagarin became an international celebrity and was awarded many medals and titles, including Hero of the Soviet Union, his nation's highest honour.

 

Vostok 1 was Gagarin's only spaceflight but he served as the backup crew to the Soyuz 1 mission, which ended in a fatal crash, killing his friend and fellow cosmonaut Vladimir Komarov. Gagarin later served as the deputy training director of the Cosmonaut Training Centre, which was subsequently named after him. He was elected as a deputy to the Soviet of the Union in 1962 and then to the Soviet of Nationalities, respectively the lower and upper chambers of the Supreme Soviet of the Soviet Union. Gagarin died in 1968 when the MiG-15 training jet he was piloting with his flight instructor Vladimir Seryogin crashed near the town of Kirzhach.

Contents

 

1 Early life and education

2 Soviet Air Force service

3 Soviet space program

3.1 Selection and training

3.2 Vostok 1

4 After the Vostok 1 flight

5 Personal life

6 Death

7 Awards and honours

7.1 Medals and orders of merit

7.2 Tributes

7.3 Statues and monuments

7.4 50th anniversary

8 See also

9 Notes

10 References

10.1 Sources

11 Further reading

12 External links

 

Early life and education

 

Yuri Gagarin was born 9 March 1934 in the village of Klushino,[1] near Gzhatsk (renamed Gagarin in 1968 after his death).[2] His parents worked on a collective farm:[3] Alexey Ivanovich Gagarin as a carpenter and Anna Timofeyevna Gagarina as a dairy farmer.[nb 2][4] Yuri was the third of four children: his siblings were brothers Valentin (1924) and Boris (1936), and sister Zoya (1927).[5][6]

 

Like millions of Soviet Union citizens, the Gagarin family suffered during the Nazi occupation of Russia during World War II. Klushino was occupied in November 1941 during the German advance on Moscow and a German officer took over the Gagarin residence. The family were allowed to build a mud hut approximately 3 by 3 metres (10 by 10 ft) inside on the land behind their house, where they spent twenty-one months until the end of the occupation.[7] His two older siblings were deported by the Germans to Poland for slave labour in 1943 and did not return until after the war in 1945.[5][8] In 1946, the family moved to Gzhatsk, where Gagarin continued his secondary education.[7]

 

In 1950, aged 16, Gagarin began an apprenticeship as a foundryman at the Lyubertsy steel plant near Moscow,[5][8] and enrolled at a local "young workers" school for seventh-grade evening classes.[9] After graduating in 1951 from both the seventh grade and the vocational school with honours in mouldmaking and foundry work,[9] he was selected for further training at the Saratov Industrial Technical School, where he studied tractors.[5][8][10] While in Saratov, Gagarin volunteered at a local flying club for weekend training as a Soviet air cadet, where he trained to fly a biplane, and later a Yak-18.[8][10] He earned extra money as a part-time dock labourer on the Volga River.[7]

Soviet Air Force service

 

In 1955, Gagarin was accepted to the 1st Chkalovsky Higher Air Force Pilots School, a flight school in Orenburg.[11][12] He initially began training on the Yak-18 already familiar to him and later graduated to training on the MiG-15 in February 1956.[11] Gagarin twice struggled to land the two-seater trainer aircraft, and risked dismissal from pilot training. However, the commander of the regiment decided to give him another chance at landing. Gagarin's flight instructor gave him a cushion to sit on, which improved his view from the cockpit, and he landed successfully. Having completed his evaluation in a trainer aircraft,[13] Gagarin began flying solo in 1957.[5]

 

On 5 November 1957, Gagarin was commissioned a lieutenant in the Soviet Air Forces having accumulated 166 hours and 47 minutes of flight time. He graduated from flight school the next day and was posted to the Luostari airbase close to the Norwegian border in Murmansk Oblast for a two-year assignment with the Northern Fleet.[14] On 7 July 1959, he was rated Military Pilot 3rd Class.[15] After expressing interest in space exploration following the launch of Luna 3 on 6 October 1959, his recommendation to the Soviet space program was endorsed and forward by Lieutenant Colonel Babushkin.[14][16] By this point, he had accumulated 265 hours of flight time.[14] Gagarin was promoted to the rank of senior lieutenant on 6 November 1959,[15] three weeks after he was interviewed by a medical commission for qualification to the space program.[14]

Soviet space program

Selection and training

See also: Vostok programme

Vostok I capsule on display at the RKK Energiya museum

 

Gagarin's selection for the Vostok programme was overseen by the Central Flight Medical Commission led by Major General Konstantin Fyodorovich Borodin of the Soviet Army Medical Service. He underwent physical and psychological testing conducted at Central Aviation Scientific-Research Hospital, in Moscow, commanded by Colonel A.S. Usanov, a member of the commission. The commission also included Colonel Yevgeniy Anatoliyevich Karpov, who later commanded the training centre, Colonel Vladimir Ivanovich Yazdovskiy, the head physician for Gagarin's flight, and Major-General Aleksandr Nikolayevich Babiychuk, a physician flag officer on the Soviet Air Force General Staff to the Commander in Chief of the Air Force.[17]

 

From a pool of 154 qualified pilots short-listed by their Air Force units, the military physicians chose 29 cosmonaut candidates, of which 20 were approved by the Credential Committee of the Soviet Government. The first twelve including Gagarin were approved on 7 March 1960 and eight more were added in a series of subsequent orders issued until June.[18] Gagarin began training at the Khodynka Airfield in downtown Moscow on 15 March 1960. The training regiment involved vigorous and repetitive physical exercises which Alexei Leonov, a member of the initial group of twelve, described as akin to training for the Olympics Games.[19] In April 1960, they began parachute training in Saratov Oblast and each completed about 40 to 50 jumps from both low and high altitude, and over land and water.[20]

 

Gagarin was a candidate favoured by his peers. When they were asked to vote anonymously for a candidate besides themselves they would like to be the first to fly, all but three chose Gagarin.[21] One of these candidates, Yevgeny Khrunov, believed that Gagarin was very focused and was demanding of himself and others when necessary.[22] On 30 May 1960, Gagarin was further selected for an accelerated training group, known as the Vanguard Six or Sochi Six,[23][nb 3] from which the first cosmonauts of the Vostok programme would be chosen. The other members of the group were Anatoliy Kartashov, Andriyan Nikolayev, Pavel Popovich, German Titov, and Valentin Varlamov. However, Kartashov and Varlamov were injured and replaced by Khrunov and Grigoriy Nelyubov.[25]

 

As several of the candidates selected for the program including Gagarin did not have higher education degrees, they were enrolled into a correspondence course program at Zhukovsky Air Force Engineering Academy. Gagarin enrolled in the program in September 1960 and did not earn his specialist diploma until early 1968.[26][27] Gagarin was also subjected to experiments that were designed to test physical and psychological endurance including oxygen starvation tests in which the cosmonauts were locked in an isolation chamber and the air slowly pumped out. He also trained for the upcoming flight by experiencing g-forces in a centrifuge.[28][25] Psychological tests included placing the candidates in an anechoic chamber in complete isolation; Gagarin was in the chamber on July 26 – August 5.[29][20] In August 1960, a Soviet Air Force doctor evaluated his personality as follows:

 

Modest; embarrasses when his humor gets a little too racy; high degree of intellectual development evident in Yuriy; fantastic memory; distinguishes himself from his colleagues by his sharp and far-ranging sense of attention to his surroundings; a well-developed imagination; quick reactions; persevering, prepares himself painstakingly for his activities and training exercises, handles celestial mechanics and mathematical formulae with ease as well as excels in higher mathematics; does not feel constrained when he has to defend his point of view if he considers himself right; appears that he understands life better than a lot of his friends.[21]

 

The Vanguard Six were given the title of pilot-cosmonaut in January 1961[25] and entered a two-day examination conducted by a special interdepartmental commission led Lieutenant-General Nikolai Kamanin, tasked with ranking of the candidates based on their mission readiness for the first human Vostok mission. On 17 January 1961, they were tested in a simulator at the M. M. Gromov Flight-Research Institute on a full-size mockup of the Vostok capsule. Gagarin, Nikolayev, Popovich, and Titov all received excellent marks on the first day of testing in which they were required to describe the various phases of the mission followed by questions from commission.[22] On the second day, they were given a written examination following which the special commission ranked Gagarin as the best candidate the first mission. He and the next two highest-ranked cosmonauts, Titov and Nelyubov, were sent to Tyuratam for final preparations.[22] Gagarin and Titov were selected to train in the flight-ready spacecraft on 7 April 1961. Historian Asif Siddiqi writes of the final selection:[30]

 

In the end, at the State Commission meeting on April 8, Kamanin stood up and formally nominated Gagarin as the primary pilot and Titov as his backup. Without much discussion, the commission approved the proposal and moved on to other last-minute logistical issues. It was assumed that in the event Gagarin developed health problems prior to liftoff, Titov would take his place, with Nelyubov acting as his backup.

 

Vostok 1

Main article: Vostok 1

 

Poyekhali!

Menu

0:00

Gagarin's voice

Problems playing this file? See media help.

 

On 12 April 1961, 6:07 am UTC, the Vostok 3KA-3 (Vostok 1) spacecraft was launched from Baikonur Cosmodrome. Aboard was Gagarin, the first human to travel into space, using the call sign Kedr (Russian: Кедр, Siberian pine or Cedar).[31] The radio communication between the launch control room and Gagarin included the following dialogue at the moment of rocket launch:

 

Korolev: Preliminary stage ... intermediate... main... LIFT-OFF! We wish you a good flight. Everything's all right.

 

Gagarin: Off we go! Goodbye, until [we meet] soon, dear friends.[32][33]

 

Gagarin's farewell to Korolev using the informal phrase Poyekhali! (Russian: Поехали!)[nb 4] later became a popular expression in the Eastern Bloc that was used to refer to the beginning of the Space Age.[35][36] The five first-stage engines fired until the first separation event, when the four side-boosters fell away, leaving the core engine. The core stage then separated while the rocket was in a suborbital trajectory, and the upper stage carried it to orbit. Once the upper stage finished firing, it separated from the spacecraft, which orbited for 108 minutes before returning to Earth in Kazakhstan.[37] Gagarin became the first to orbit the Earth.[31]

File:1961-04-19 First Pictures-Yuri Gagarin-selection.ogvPlay media

An April 1961 newsreel of Gagarin arriving in Moscow to be greeted by First Secretary Nikita Khrushchev.

 

"The feeling of weightlessness was somewhat unfamiliar compared with Earth conditions. Here, you feel as if you were hanging in a horizontal position in straps. You feel as if you are suspended", Gagarin wrote in his post-flight report.[38] He also wrote in his autobiography released the same year that he sang the tune "The Motherland Hears, The Motherland Knows" (Russian: "Родина слышит, Родина знает") during re-entry.[39] Gagarin was qualified a Military Pilot 1st Class and promoted to the rank of major in a special order given during his flight.[15][39]

 

At about 23,000 feet (7,000 m), Gagarin ejected from the descending capsule as planned and landed using a parachute. There were concerns Gagarin's spaceflight record would not be certified by the Fédération Aéronautique Internationale (FAI), the world governing body for setting standards and keeping records in the field, which at the time required that the pilot land with the craft.[40] Gagarin and Soviet officials initially refused to admit that he had not landed with his spacecraft,[41] an omission which became apparent after Titov's subsequent flight on Vostok 2 four months later. Gagarin's spaceflight records were nonetheless certified and again reaffirmed by the FAI, which revised it rules, and acknowledge that the crucial steps of the safe launch, orbit, and return of the pilot had been accomplished. Gagarin continues to be internationally recognised as the first human in space and first to orbit the Earth.[42]

After the Vostok 1 flight

Gagarin in Warsaw, 1961

 

Gagarin's flight was a triumph for the Soviet space program and he became a national hero of the Soviet Union and Eastern Bloc, as well as a worldwide celebrity. Newspapers around the globe published his biography and details of his flight. He was escorted in a long motorcade of high-ranking officials through the streets of Moscow to the Kremlin where, in a lavish ceremony, Nikita Khrushchev awarded him the title Hero of the Soviet Union. Other cities in the Soviet Union also held mass demonstrations, the scale of which were second only to World War II Victory Parades.[43]

Gagarin and Valentina Tereshkova (seated to his right) sign autographs in 1964

 

Gagarin gained a reputation as an adept public figure and was noted for his charismatic smile.[44][45][46] On 15 April 1961, accompanied by official from the Soviet Academy of Sciences, he answered questions at a press conference in Moscow reportedly attended by 1,000 reporters.[47] Gagarin visited the United Kingdom three months after the Vostok 1 mission, going to London and Manchester.[48][44] While in Manchester, despite heavy rain, he refused an umbrella, insisted that the roof of the convertible car he was riding in remain open, and stood so the cheering crowds could see him.[44][49] Gagarin toured widely abroad, accepting the invitation of about 30 countries.[50] In just the first four months, he also went to Brazil, Bulgaria, Canada, Cuba, Czechoslovakia, Finland, Hungary, and Iceland.[51]

 

In 1962, Gagarin began serving as a deputy to the Soviet of the Union,[52] and was elected to the Central Committee of the Young Communist League. He later returned to Star City, the cosmonaut facility, where he spent several years working on designs for a reusable spacecraft. He became a lieutenant colonel of the Soviet Air Forces on 12 June 1962, and received the rank of colonel on 6 November 1963.[15] On 20 December 1963, Gagarin became Deputy Training Director of the Star City cosmonaut training base.[53] Soviet officials, including cosmonaut overseerer Nikolai Kamanin, tried to keep Gagarin away from any flights, being worried about losing their hero in an accident noting that he was "too dear to mankind to risk his life for the sake of an ordinary space flight".[54] Kamanin was also concerned by Gagarin's drinking and believed the sudden rise to fame had taken its toll on the cosmonaut. While acquaintances say Gagarin had been a "sensible drinker", his touring schedule placed him in social situations in which he was increasingly expected to drink alcohol.[5][10]

Gagarin with U.S. Vice President Hubert Humphrey, French Prime Minister Georges Pompidou and the Gemini 4 astronauts at the 1965 Paris Air Show

 

Two years later, he was re-elected as a deputy of the Soviet Union but this time to the Soviet of Nationalities, the upper chamber of legislature.[52] The following year, he began to re-qualify as a fighter pilot[55] and was backup pilot for his friend Vladimir Komarov on the Soyuz 1 flight after five years without piloting duty. Kamanin had opposed Gagarin's reassignment to cosmonaut training; he had gained weight and his flying skills had deteriorated. Despite this, he remained a strong contender for Soyuz 1 until he was replaced by Komarov in April 1966 and reassigned to Soyuz 3.[56]

 

The Soyuz 1 launch was rushed due to implicit political pressures[57] and despite Gagarin's protests that additional safety precautions were necessary.[58] Gagarin accompanied Komarov to the rocket before launch and relayed instructions to Komarov from ground control following multiple system failures aboard the spacecraft.[59] Despite their best efforts, Soyuz 1 crash landed after its parachutes failed to open, killing Komarov instantly.[60] After the Soyuz 1 crash, Gagarin was permanently banned from training for and participating in further spaceflights.[61] He was also grounded from flying aircraft solo, a demotion he worked hard to lift. He was temporarily relieved of duties to focus on academics with the promise that he would be able to resume flight training.[62] On 17 February 1968, Gagarin successfully defended his aerospace engineering thesis on the subject of spaceplane aerodynamic configuration and graduated cum laude from Zhukovsky Air Force Engineering Academy.[27][63][62]

Personal life

Gagarin and his wife Valentina clapping at a concert in Moscow in 1964.

Gagarin and his wife Valentina at a concert in Moscow in 1964.

 

Gagarin was a keen sportsman and fond of ice hockey as a goal keeper.[64] He was also a basketball fan and coached the Saratov Industrial Technical School team, as well as being a referee.[65]

 

In 1957, while a cadet in flight school, Gagarin met Valentina Goryacheva at the May Day celebrations at the Red Square in Moscow.[66] She was a medical technician who graduated from Orenburg Medical School.[8][10] They were married on 7 November 1957,[8] the same day Gagarin graduated from Orenburg, and they had two daughters.[67][68] Yelena Yurievna Gagarina, born 1959,[68] is an art historian who has worked as the director-general of the Moscow Kremlin Museums since 2001;[69][70] and Galina Yurievna Gagarina, born 1961,[68] is a professor of economics and the department chair at Plekhanov Russian University of Economics in Moscow.[69][71] Following his rise to fame, at a Black Sea resort in September 1961, he was reportedly caught by his wife during a liaison with a nurse who had aided him after a boating incident. He attempted to escape through a window and jumped off a second floor balcony. The resulting injury left a permanent scar above his left eyebrow.[5][10]

Death

Plaque on a brick wall with inscription: Юрий Алексеевич Гагарин, 1934-03-09–1968-03-27

Plaque indicating Gagarin's interment in the Kremlin Wall

 

On 27 March 1968, while on a routine training flight from Chkalovsky Air Base, Gagarin and flight instructor Vladimir Seryogin died when their MiG-15UTI crashed near the town of Kirzhach. The bodies of Gagarin and Seryogin were cremated and their ashes were buried in the walls of the Kremlin.[72] Wrapped in secrecy, the cause of the crash that killed Gagarin is uncertain and became the subject of several theories.[73][74] At least three investigations into the crash were conducted separately by the Air Force, official government commissions, and the KGB.[75][76] According to a biography of Gagarin by Jamie Doran and Piers Bizony, Starman: The Truth Behind the Legend of Yuri Gagarin, the KGB worked "not just alongside the Air Force and the official commission members but against them."[75]

 

The KGB's report declassified in March 2003 dismissed various conspiracy theories and instead indicated the actions of airbase personnel contributed to the crash. The report states that an air-traffic controller provided Gagarin with outdated weather information and that by the time of his flight, conditions had deteriorated significantly. Ground crew also left external fuel tanks attached to the aircraft. Gagarin's planned flight activities needed clear weather and no outboard tanks. The investigation concluded Gagarin's aircraft entered a spin, either due to a bird strike or because of a sudden move to avoid another aircraft. Because of the out-of-date weather report, the crew believed their altitude was higher than it was and could not react properly to bring the MiG-15 out of its spin.[76] Another theory, advanced in 2005 by the original crash investigator, hypothesizes that a cabin air vent was accidentally left open by the crew or the previous pilot, leading to oxygen deprivation and leaving the crew incapable of controlling the aircraft.[73] A similar theory, published in Air & Space magazine, is that the crew detected the open vent and followed procedure by executing a rapid dive to a lower altitude. This dive caused them to lose consciousness and crash.[74]

 

On 12 April 2007, the Kremlin vetoed a new investigation into the death of Gagarin. Government officials said they saw no reason to begin a new investigation.[77] In April 2011, documents from a 1968 commission set up by the Central Committee of the Communist Party to investigate the accident were declassified. The documents revealed that the commission's original conclusion was that Gagarin or Seryogin had manoeuvered sharply, either to avoid a weather balloon or to avoid "entry into the upper limit of the first layer of cloud cover", leading the jet into a "super-critical flight regime and to its stalling in complex meteorological conditions".[78]

A Russian MiG-15UTI, the same type as Gagarin was flying

 

Cosmonaut Alexei Leonov, a member of a state commission established to investigate Gagarin's death, was conducting parachute training sessions that day and heard "two loud booms in the distance". He believes that a Sukhoi Su-15 was flying below its minimum altitude and, "without realizing it because of the terrible weather conditions, he passed within 10 or 20 meters of Yuri and Seregin's plane while breaking the sound barrier". The resulting turbulence would have sent the MiG-15UTI into an uncontrolled spin. Leonov said the first boom he heard was that of the jet breaking the sound barrier and the second was Gagarin's plane crashing.[79] In a June 2013 interview with Russian television network RT, Leonov said a report on the incident confirmed the presence of a second, "unauthorized" Su-15 flying in the area. However, as a condition of being allowed to discuss the declassified report, Leonov was barred from disclosing the name of the Su-15 pilot who was 80 years old and in poor health as of 2013.[80]

Awards and honours

Medals and orders of merit

Jânio Quadros, President of Brazil, decorated Gagarin in 1961.

 

On 14 April 1961, Gagarin was honoured with a 12-mile (19 km) parade attended by millions of people that concluded at the Red Square. After a short speech, he was bestowed the Hero of the Soviet Union,[81][82] Order of Lenin,[81] Merited Master of Sports of the Soviet Union[83] and the first Pilot-Cosmonaut of the USSR.[82] On 15 April, the Soviet Academy of Sciences awarded him with the Konstantin Tsiolkovsky Gold Medal, named after the Russian pioneer of space aeronautics.[84] Gagarin had also been awarded four Soviet commemorative medals over the course of his career.[15]

 

He was honoured as a Hero of Socialist Labor (Czechoslovakia) on 29 April 1961,[85][86] and Hero of Socialist Labor (Bulgaria, including the Order of Georgi Dimitrov) on 24 May.[15][chronology citation needed] On the eighth anniversary of the beginning of Cuban Revolution (26 July), President Osvaldo Dorticos of Cuba presented him with the first Commander of the Order of Playa Girón, a newly created medal.[87]

 

Gagarin was also awarded the 1960 Gold Air Medal and the 1961 De la Vaulx Medal from the Fédération Aéronautique Internationale in Switzerland.[88] He received numerous awards from other nations that year, including the Star of the Republic of Indonesia (2nd Class), the Order of the Cross of Grunwald (1st Degree) in Poland, the Order of the Flag of the Republic of Hungary, the Hero of Labor award from Democratic Republic of Vietnam,[15] the Italian Columbus Day Medal,[89] and a Gold Medal from the British Interplanetary Society.[90][91] President Jânio Quadros of Brazil decorated Gagarin on 2 August 1961 with the Order of Aeronautical Merit, Commander grade.[92] During a tour of Egypt in late January 1962, Gagarin received the Order of the Nile[93] and the golden keys to the gates of Cairo.[50] On 22 October 1963, Gagarin and Valentina Tereshkova were honoured with the Order of Karl Marx from the German Democratic Republic.[94]

Tributes

 

The date of Gagarin's space flight, 12 April, has been commemorated. Since 1962, it has been celebrated in the USSR and most of its former territories as Cosmonautics Day.[95] Since 2000, Yuri's Night, an international celebration, is held annually to commemorate milestones in space exploration.[96] In 2011, it was declared the International Day of Human Space Flight by the United Nations.[97]

Yuri Gagarin statue at the Royal Greenwich Observatory in London

 

A number of buildings and locations have been named for Gagarin. The Yuri Gagarin Cosmonaut Training Center in Star City, Russia, was named on 30 April 1968.[98] The launch pad at Baikonur Cosmodrome from which Sputnik 1 and Vostok 1 were launched is now known as Gagarin's Start. Gagarin Raion in Sevastopol, Ukraine, was named after him during the period of the Soviet Union. The Russian Air Force Academy was renamed Gagarin Air Force Academy in 1968.[99] A street in Warsaw, Poland, is called Yuri Gagarin Street.[100] The town of Gagarin, Armenia was renamed in his honour in 1961.[101]

 

Gagarin has been honoured on the Moon by astronauts and astronomers. During the American space program's Apollo 11 mission in 1969, astronauts Neil Armstrong and Buzz Aldrin left a memorial satchel containing medals commemorating Gagarin and fellow cosmonaut Vladimir Komarov on the Moon's surface.[102][103] In 1971, Apollo 15 astronauts David Scott and James Irwin left the small Fallen Astronaut sculpture at their landing site as a memorial to the American astronauts and Soviet cosmonauts who died in the Space Race; the names on its plaque included Yuri Gagarin and 14 others.[104][105] In 1970, a 262 km (163 mi)-wide crater on the far side after him.[106] Gagarin was inducted as a member of the 1976 inaugural class of the International Space Hall of Fame in New Mexico.[107]

 

Gagarin is memorialised in music; a cycle of Soviet patriotic songs titled The Constellation Gagarin (Russian: Созвездье Гагарина, tr. Sozvezdie Gagarina) was written by Aleksandra Pakhmutova and Nikolai Dobronravov in 1970–1971.[108] The most famous of these songs refers to Gagarin's poyekhali!: in the lyrics, "He said 'let's go!' He waved his hand".[35][108] He was the inspiration for the pieces "Hey Gagarin" by Jean-Michel Jarre on Métamorphoses, "Gagarin" by Public Service Broadcasting, and "Gagarin, I loved you" by Undervud.[109]

Russian ten-ruble commemorating Gagarin in 2001

 

Vessels have been named for Gagarin; Soviet tracking ship Kosmonavt Yuri Gagarin was built in 1971[110] and the Armenian airline Armavia named their first Sukhoi Superjet 100 in his honour in 2011.[111]

 

Two commemorative coins were issued in the Soviet Union to honour the 20th and 30th anniversaries of his flight: a one-ruble coin in copper-nickel (1981) and a three-ruble coin in silver (1991). In 2001, to commemorate the 40th anniversary of Gagarin's flight, a series of four coins bearing his likeness was issued in Russia; it consisted of a two-ruble coin in copper-nickel, a three-ruble coin in silver, a ten-ruble coin in brass-copper and nickel, and a 100-ruble coin in silver.[112] In 2011, Russia issued a 1,000-ruble coin in gold and a three-ruble coin in silver to mark the 50th anniversary of his flight.[113]

 

In 2008, the Kontinental Hockey League named their championship trophy the Gagarin Cup.[114] In a 2010 Space Foundation survey, Gagarin was ranked as the sixth-most-popular space hero, tied with Star Trek's fictional James T. Kirk.[115] A Russian docudrama titled Gagarin: First in Space was released in 2013. Previous attempts at portraying Gagarin were disallowed; his family took legal action over his portrayal in a fictional drama and vetoed a musical.[116]

Statues and monuments

 

There are statues of Gagarin and monuments to him located in Gagarin (Smolensk Oblast), Orenburg, Cheboksary, Irkutsk, Izhevsk, Komsomolsk-on-Amur, and Yoshkar-Ola in Russia, as well as in Nicosia, Cyprus, Druzhkivka, Ukraine, Karaganda, Kazakhstan, and Tiraspol, Moldova. On 4 June 1980, Monument to Yuri Gagarin in Gagarin Square, Leninsky Avenue, Moscow, was opened.[117] The monument is mounted to a 38 m (125 ft) tall pedestal and is constructed of titanium. Beside the column is a replica of the descent module used during his spaceflight.[118]

Bust of Gagarin at Birla Planetarium in Kolkata, India

 

In 2011, a statue of Gagarin was unveiled at Admiralty Arch in The Mall in London, opposite the permanent sculpture of James Cook. It is a copy of the statue outside Gagarin's former school in Lyubertsy.[119] In 2013, the statue was moved to a permanent location outside the Royal Observatory, Greenwich.[120]

 

In 2012, a statue was unveiled at the site of NASA's original spaceflight headquarters on South Wayside Drive in Houston. The sculpture was completed in 2011 by artist and cosmonaut Alexei Leonov and was a gift to Houston by various Russian organisations. Houston Mayor Annise Parker, NASA Administrator Charles Bolden, and Russian Ambassador Sergey Kislyak were present for the dedication.[121][122] The Russian Federation presented a bust of Gagarin to several cities in India including one that was unveiled at the Birla Planetarium in Kolkata in February 2012.[123]

 

In April 2018, a bust of Gagarin erected on the street in Belgrade, Serbia, that bears his name was removed, after less than week. A new work was commissioned following the outcry over the disproportionately small size of its head which locals said was an "insult" to Gagarin.[124][125] Belgrade City Manager Goran Vesic stated that neither the city, the Serbian Ministry of Culture, nor the foundation that financed it had prior knowledge of the design.[126]

50th anniversary

50th anniversary stamp of Ukraine

 

The 50th anniversary of Gagarin's journey into space was marked in 2011 by tributes around the world. A film titled First Orbit was shot from the International Space Station, combining sound recordings from the original flight with footage of the route taken by Gagarin.[127] The Russian, American, and Italian crew of Expedition 27 aboard the ISS sent a special video message to wish the people of the world a "Happy Yuri's Night", wearing shirts with an image of Gagarin.[128]

 

The Central Bank of the Russian Federation released gold and silver coins to commemorate the anniversary.[129] The Soyuz TMA-21 spacecraft was named Gagarin with the launch in April 2011 to coincide with the 50th anniversary of the first manned space mission.

The USB Wifi receiver at the top of the "pole" protected by its plastic bag and secured using cable ties.

146. - The External Oblique Muscles.

 

Original photograph taken with a Polaroid SX-70 Alpha1 SE using Impossible Project PX680 First Flush instant film.

 

Emulsion transfer onto heavyweight matt laser print of a scan from Gray's Anatomy 1st edition reprint.

 

See the full series here

 

Had some trouble with this, mostly due to the age of the film I think, so contrast has been slightly boosted after scanning.

The finished ariel.

Snorkling with Sea Lions off Floreana. It was amazing as they were so playful, one thought chewing on my flippers was a great game and another liked swimming really close and blowing bubbles in my face!

 

Galapagos Sea Lion

The Galápagos Sea Lion (Zalophus wollebaeki) breeds on the Galápagos Islands and – in smaller numbers – on Isla de la Plata (to Ecuador). Being fairly social, and one of the most numerous species in the Galápagos archipelago, they are often spotted sun-bathing on sandy shores or rock groups or gliding gracefully through the surf. Their loud “bark”, playful nature, and graceful agility in water make them the “welcoming party” of the islands. They are lightly smaller than their Californian relatives, Galápagos Sea Lions range from 150 to 250 cm in length and weigh between 50 to 400 kg, with the males much larger than females. Adult males also tend to have a thicker, more robust neck, chest, and shoulders in comparison to their slender abdomen. Females are somewhat opposite males with a longer, more slender neck and thick torso. Once sexually mature, a male’s sagittal crest enlarges, forming a small, characteristic bump-like projection on their forehead. Galápagos Sea Lions, compared to California sea lions, have a slightly smaller sagittal crest and a shorter muzzle. Adult females and juveniles lack this physical characteristic altogether with a nearly flat head and little or no forehead. Both male and female sea lions have a pointy, whiskered nose and somewhat long, narrow muzzle. The young pups are almost dog-like in profile. Another characteristic that defines the sea lion are their external ear-like pinnae flaps which distinguish them from their close relative in which they are often confused with, the seal. The fore-flippers have a short fur extending from the wrist to the middle of the dorsal fin surface, but other than that, the flippers are covered in black, leathery skin. Although somewhat clumsy on land with their flippers, sea lions are amazingly agile in water. With their streamline bodies and flipper-like feet, they easily propel themselves through crashing surf and dangerously sharp coastal rocks. They also have the ability to control their flippers independently and thus change directions with ease and have more control over their body on land. When wet, sea lions are a shade of dark brown, but once dry, their color varies greatly. The females tend to be a lighter shade than the males and the pups a chestnut brown. Born with a longer, brownish-black lanugo, a pup's coat gradually fades to brown within the first five months of life. At this time, they undergo their first molt resulting in their adult coat. Feeding mostly on sardines, Galápagos Sea Lions sometimes travel ten to fifteen kilometers from the coast over the span of days to hunt for their prey. This is when they come into contact with their biggest predators: sharks and killer whales. Injuries and scars from attacks are often visible. Galápagos Sea Lions are especially vulnerable to human activity. Their inquisitive and social nature makes them more likely to approach areas inhabited by humans, and thus come into contact with human waste, fishing nets, and hooks. They occupy many different shoreline types from steep, rocky cliff sides to low-lying sandy beaches. To avoid overheating during the day, sea lions will take refuge from the sun under vegetation, rocks, and cliffs, and wade into tidal pools. Not only are sea lions social, they are also quite vocal. Adult male Galápagos Sea Lions often bark in long, repeated sequences that are loud and distinctive. Females and juveniles do not produce this repetitive bark, but both sexes and the younger pups will growl. From birth, a mother sea lion recognizes her pup’s distinct bark and can pin point it from a crowd of thirty or more barking sea lions. On land, sea lions form colonies at their hauling-out areas. Adult males known as Bulls are the head of the Colony, growing up to 7 ft (2 m) long and weighing up to 800 lb (363 kg). As males grow larger, they fight to win dominance of a harem of between 5 and 25 cows and the surrounding territory. Swimming from border to border of his colony, the dominant bull jealously defends his coastline against all other adult males. While patrolling his area, he frequently rears his head out of the water and barks, as an indication of his territorial ownership. The average dominant bull holds his territory for only a few months, until he is challenged by another male. On land, these fights start by stretching out the neck and barking in attempt to test each other’s bravery. If this isn’t enough to scare the opponent off, they begin pushing each other and biting around the neck area. If males weren’t equipped with a thick, muscular neck, their vital organs would be easily damaged during these fights. Blood, is often drawn, however, and many male sea lions have battle scars due to these territorial competitions. Losers are dramatically chased far from their territory by the new dominant bull with much splashing. Because there is only one male in each harem, there is always a surplus of “bachelor” male sea lions. They usually congregate fairly peaceably on less favorable areas of the coastline in “bachelor colonies.”. Because the dominant male of the harem cannot feed while defending his colony, he eventually becomes too tired and weak, and is overpowered by the well-nourished, fresh bull. Breeding takes place from May all the way through to January. Because of this prolonged breeding season and the extensive care required by the pups from their mother, there are dependent pups in the colonies year round. Each cow in the harem has a single pup born a year after conception. After about a week of continuous attention from birth, the female returns to the ocean and begins to forage, and just a week after that, the pup will follow her and begin to develop its swimming skills. When the pup is two to three weeks old the cow will mate again. The mothers will take the young pups with them into the water while nursing until around the 11th month when the pups are weaned from their mother’s milk and become dependent on their own hunting skills. The pups have a strong bond with their mother. The cow will nurture a pup for up to three years. In that time the cow and the pup will recognize each other's bark from the rest of the colony. Within the colony sea lion pups live together in a rookery. Pups can be seen together napping, playing, and feeding. It is not uncommon to see one cow 'baby-sitting' a group of pups while the other cows go off to feed.

 

Floreana (Champions Islet)

Located approximately 4 to 5 hours west of Española and equal distance south of Santa Cruz, this island has long been a favorite site of visitors including pirates, whalers and early settlers. One of the oldest islands Floreana illustrates the aging process of a volcanic island. Unlike the younger western islands, Floreana's volcano has been long extinct and is in the advanced stages of erosion. The erosion process gave the island the nutrients and soils need to sustain plant life. The combination of this rich soil and a good water supply have given the highlands of Floreana a diversified landscaping of native and introduced flora. Floreana is best known for its colorful history of buccaneers, whalers, convicts, and colonists. In 1793 British whalers established the Post Office Barrel to send letters to and from England. This tradition has continued over the years, and even today visitors may drop off and pick up letters, without stamps, to be carried to far destinations. Punta Cormorant offers two highly contrasting beaches. The landing beach is of volcanic origin and is composed of olivine crystals, giving it a greenish tinge. At the end of the short trail is a carbonate beach of extremely fine white sand. Formed by the erosion of coral skeletons, it is a nesting site for green sea turtles. In the 1930's Floreana was the setting for intrigue and mystery. A German dentist and his mistress, a young family (the Wittmer family who still live on the island) and a self-styled baroness with three men came to settle in the island. Shortly after the baroness and her lovers arrived chaos began. The baroness and her entourage terrorized the other inhabitants while planning to build a luxury hotel. Eventually the baroness, two of her lovers and the dentist all turned up missing or dead. There has been much investigation searching for what really happened on Floreana, but there have never been any hard answers. John Treherne wrote of these people in "The Galapagos Affair". Located just off Punta Cormorant, Champions Islet is the best snorkeling in the Galapagos! To see the Devil’s Crown you need to go underwater, an almost completely submerged volcano, which erosion has transformed the cone into a series of jagged peaks creating the "Devil's Crown". The remains of the volcano create a haven for seabirds such as boobies, pelicans and frigates. Red-billed tropical birds can be seen nesting in the crevices. The highlight of the visit is snorkeling in the center of the crater. You will play with sea lions, while swimming with schools of colorful king angel fish, balloon fish, hawkfish, scrawled filefish, yellowtail grunts, tiger snake eels, white-tipped sharks, eagle rays, amberjacks, wrasses, hammerhead sharks, and sea turtles. The water is a bit rough and the current is strong. The east to west current provides a fun ride as it pushes you through the crown. There is a tube on the western side that you can swim through if you are a strong swimmer (approximately 10-15 feet down) and come out on the other side.

 

Galapagos Islands

The Galápagos Islands (official name: Archipiélago de Colón; other Spanish names: Islas de Colón or Islas Galápagos) are an archipelago of volcanic islands distributed around the equator in the Pacific Ocean, some 900 km west of Ecuador. It is a UNESCO World Heritage site: wildlife is its most notable feature. Because of the only very recent arrival of man the majority of the wildlife has no fear of humans and will allow visitors to walk right up them, often having to step over Iguanas or Sea Lions.The Galápagos islands and its surrounding waters are part of a province, a national park, and a biological marine reserve. The principal language on the islands is Spanish. The islands have a population of around 40,000, which is a 40-fold expansion in 50 years. The islands are geologically young and famed for their vast number of endemic species, which were studied by Charles Darwin during the voyage of the Beagle. His observations and collections contributed to the inception of Darwin's theory of evolution by natural selection.

Singapore (Listeni/ˈsɪŋɡəpɔːr/), officially the Republic of Singapore, and often referred to as the Lion City, the Garden City, and the Red Dot, is a global city and sovereign state in Southeast Asia and the world's only island city-state. It lies one degree (137 km) north of the equator, at the southernmost tip of continental Asia and peninsular Malaysia, with Indonesia's Riau Islands to the south. Singapore's territory consists of the diamond-shaped main island and 62 islets. Since independence, extensive land reclamation has increased its total size by 23% (130 km2), and its greening policy has covered the densely populated island with tropical flora, parks and gardens.

 

The islands were settled from the second century AD by a series of local empires. In 1819, Sir Stamford Raffles founded modern Singapore as a trading post of the East India Company; after the company collapsed, the islands were ceded to Britain and became part of its Straits Settlements in 1826. During World War II, Singapore was occupied by Japan. It gained independence from Britain in 1963, by uniting with other former British territories to form Malaysia, but was expelled two years later over ideological differences. After early years of turbulence, and despite lacking natural resources and a hinterland, the nation developed rapidly as an Asian Tiger economy, based on external trade and its human capital.

 

Singapore is a global commerce, finance and transport hub. Its standings include: "easiest place to do business" (World Bank) for ten consecutive years, most "technology-ready" nation (WEF), top International-meetings city (UIA), city with "best investment potential" (BERI), 2nd-most competitive country (WEF), 3rd-largest foreign exchange centre, 3rd-largest financial centre, 3rd-largest oil refining and trading centre and one of the top two busiest container ports since the 1990s. Singapore's best known global brands include Singapore Airlines and Changi Airport, both amongst the most-awarded in their industry; SIA is also rated by Fortune surveys as Asia's "most admired company". For the past decade, it has been the only Asian country with the top AAA sovereign rating from all major credit rating agencies, including S&P, Moody's and Fitch.

 

Singapore ranks high on its national social policies, leading Asia and 11th globally, on the Human Development Index (UN), notably on key measures of education, healthcare, life expectancy, quality of life, personal safety, housing. Although income inequality is high, 90% of citizens own their homes, and the country has one of the highest per capita incomes, with low taxes. The cosmopolitan nation is home to 5.5 million residents, 38% of whom are permanent residents and other foreign nationals. Singaporeans are mostly bilingual in a mother-tongue language and English as their common language. Its cultural diversity is reflected in its extensive ethnic "hawker" cuisine and major festivals - Chinese, Malay, Indian, Western - which are all national holidays. In 2015, Lonely Planet and The New York Times listed Singapore as their top and 6th best world destination to visit respectively.

 

The nation's core principles are meritocracy, multiculturalism and secularism. It is noted for its effective, pragmatic and incorrupt governance and civil service, which together with its rapid development policies, is widely cited as the "Singapore model". Gallup polls shows 84% of its residents expressed confidence in the national government, and 85% in its judicial systems - one of the highest ratings recorded. Singapore has significant influence on global affairs relative to its size, leading some analysts to classify it as a middle power. It is ranked as Asia's most influential city and 4th in the world by Forbes.

 

Singapore is a unitary, multiparty, parliamentary republic, with a Westminster system of unicameral parliamentary government. The People's Action Party has won every election since self-government in 1959. One of the five founding members of the ASEAN, Singapore is also the host of the Asia-Pacific Economic Cooperation (APEC) Secretariat, and a member of the East Asia Summit, Non-Aligned Movement, and the Commonwealth of Nations.

 

ETYMOLOGY

The English name of Singapore is derived from the Malay word, Singapura, which was in turn derived from Sanskrit (Singa is "lion", Pura "city"; Sanskrit: सिंहपुर, IAST: Siṃhápura), hence the customary reference to the nation as the Lion City, and its inclusion in many of the nation's symbols (e.g., its coat of arms, Merlion emblem). However, it is unlikely that lions ever lived on the island; Sang Nila Utama, who founded and named the island Singapura, most likely saw a Malayan tiger. It is also known as Pulau Ujong, as far back as the 3rd century, literally 'island at the end' (of the Malay Peninsula) in Malay.

 

Since the 1970s, Singapore has also been widely known as the Garden City, owing to its extensive greening policy covering the whole island, a priority of its first prime minister Lee Kuan Yew, dubbed the nation's "Chief Gardener". The nation's conservation and greening efforts contributed to Singapore Botanic Gardens being the only tropical garden to be inscribed by UNESCO as a World Heritage Site. The nickname, Red Dot, is a reference to its size on the map, contrasting with its achievements. In 2015, Singapore's Golden Jubilee year, the celebratory "SG50" branding is depicted inside a red dot.

 

HISTORY

Temasek ('Sea Town' in the Malay language), an outpost of the Sumatran Srivijaya empire, is the earliest written record relating to the area now called Singapore. In the 13th century, the Kingdom of Singapura was established on the island and it became a trading port city. However, there were two major foreign invasions before it was destroyed by the Majapahit in 1398. In 1613, Portuguese raiders burned down the settlement, which by then was nominally part of the Johor Sultanate and the island sank into obscurity for the next two centuries, while the wider maritime region and much trade was under Dutch control.

 

BRITISH COLONISATION 1819-1942

In 1819, Thomas Stamford Raffles arrived and signed a treaty with Sultan Hussein Shah of Johor, on behalf of the British East India Company, to develop the southern part of Singapore as a British trading post. In 1824, the entire island, as well as the Temenggong, became a British possession after a further treaty with the Sultan. In 1826, Singapore became part of the Straits Settlements, under the jurisdiction of British India, becoming the regional capital in 1836.

 

Prior to Raffles' arrival, there were only about a thousand people living on the island, mostly indigenous Malays along with a handful of Chinese. By 1860, the population had swelled to more than 80,000 and more than half were Chinese. Many immigrants came to work at rubber plantations and, after the 1870s, the island became a global centre for rubber exports.

 

After the First World War, the British built the large Singapore Naval Base. Lieutenant General Sir William George Shedden Dobbie was appointed General Officer Commanding of the Malaya Command on 8 November 1935, holding the post until 1939;

 

WORLD WAR II AND JAPANESE OCCUPATION 1942-45

in May 1938, the General Officer Commanding of the Malaya Command warned how Singapore could be conquered by the Japanese via an attack from northern Malaya, but his warnings went unheeded. The Imperial Japanese Army invaded British Malaya, culminating in the Battle of Singapore. When the British surrendered on 15 February 1942, British Prime Minister Winston Churchill called the defeat "the worst disaster and largest capitulation in British history". Between 5,000 and 25,000 ethnic Chinese people were killed in the subsequent Sook Ching massacre.

 

From November 1944 to May 1945, the Allies conducted an intensive bombing of Singapore.

 

RETURN OF BRITISH 1945-59

After the surrender of Japan was announced in the Jewel Voice Broadcast by the Japanese Emperor on 15 August 1945 there was a breakdown of order and looting and revenge-killing were widespread. The formal Japanese Occupation of Singapore was only ended by Operation Tiderace and the formal surrender on 12 September 1945 at Singapore City Hall when Lord Louis Mountbatten, Supreme Allied Commander of Southeast Asia Command, accepted the capitulation of Japanese forces in Southeast Asia from General Itagaki Seishiro.

 

A British Military Administration was then formed to govern the island. On 1 April 1946, the Straits Settlements were dissolved and Singapore became a separate Crown Colony with a civil administration headed by a Governor. Much of the infrastructure had been destroyed during the war, including the harbour, electricity, telephone and water supply systems. There was also a shortage of food leading to malnutrition, disease, and rampant crime and violence. High food prices, unemployment, and workers' discontent culminated into a series of strikes in 1947 causing massive stoppages in public transport and other services. In July 1947, separate Executive and Legislative Councils were established and the election of six members of the Legislative Council was scheduled for the following year. By late 1947, the economy began to recover, facilitated by a growing demand for tin and rubber around the world, but it would take several more years before the economy returned to pre-war levels.

 

The failure of Britain to defend Singapore had destroyed its credibility as an infallible ruler in the eyes of Singaporeans. The decades after the war saw a political awakening amongst the local populace and the rise of anti-colonial and nationalist sentiments, epitomized by the slogan Merdeka, or "independence" in the Malay language.

 

During the 1950s, Chinese Communists with strong ties to the trade unions and Chinese schools carried out armed uprising against the government, leading to the Malayan Emergency and later, the Communist Insurgency War. The 1954 National Service Riots, Chinese middle schools riots, and Hock Lee bus riots in Singapore were all linked to these events.

 

David Marshall, pro-independence leader of the Labour Front, won Singapore's first general election in 1955. He led a delegation to London, but Britain rejected his demand for complete self-rule. He resigned and was replaced by Lim Yew Hock, whose policies convinced Britain to grant Singapore full internal self-government for all matters except defence and foreign affairs.

 

SELF-GOVERNMENT 1959-1963

During the May 1959 elections, the People's Action Party won a landslide victory. Singapore became an internally self-governing state within the Commonwealth, with Lee Kuan Yew as its first Prime Minister. Governor Sir William Allmond Codrington Goode served as the first Yang di-Pertuan Negara (Head of State), and was succeeded by Yusof bin Ishak, who became the first President of Singapore in 1965.

 

MERGER WITH MALAYSIA 1963-65

As a result of the 1962 Merger Referendum, on 31 August 1963 Singapore joined with the Federation of Malaya, the Crown Colony of Sarawak and the Crown Colony of North Borneo to form the new federation of Malaysia under the terms of the Malaysia Agreement. Singaporean leaders chose to join Malaysia primarily due to concerns over its limited land size, scarcity of water, markets and natural resources. Some Singaporean and Malaysian politicians were also concerned that the communists might form the government on the island, a possibility perceived as an external threat to the Federation of Malaya.However, shortly after the merger, the Singapore state government and the Malaysian central government disagreed on many political and economic issues, and communal strife culminated in the 1964 race riots in Singapore. After many heated ideological conflicts between the two governments, on 9 August 1965, the Malaysian Parliament voted 126 to 0 to expel Singapore from Malaysia with Singaporean delegates not present.

 

INDEPENDENCE 1965 TO PRESENT

Singapore gained independence as the Republic of Singapore (remaining within the Commonwealth of Nations) on 9 August 1965. Race riots broke out once more in 1969. In 1967, the country co-founded ASEAN, the Association of Southeast Asian Nations, and in 1970 it joined the Non-Aligned Movement. Lee Kuan Yew became Prime Minister, leading its Third World economy to First World affluence in a single generation. His emphasis on rapid economic growth, support for business entrepreneurship, limitations on internal democracy, and close relationships with China set the new nation's policies for the next half-century.

 

In 1990, Goh Chok Tong succeeded Lee as Prime Minister, while the latter continued serving in the Cabinet as Senior Minister until 2004, and then Minister Mentor until May 2011. During Goh's tenure, the country faced the 1997 Asian financial crisis, the 2003 SARS outbreak and terrorist threats posed by Jemaah Islamiyah.

 

In 2004, Lee Hsien Loong, the eldest son of Lee Kuan Yew, became the country's third Prime Minister. Goh Chok Tong remained in Cabinet as the Senior Minister until May 2011, when he was named Emeritus Senior Minister despite his retirement. He steered the nation through the 2008 global financial crisis, resolved the disputed 79-year old Malayan railways land, and introduced integrated resorts. Despite the economy's exceptional growth, PAP suffered its worst election results in 2011, winning 60% of votes, amidst hot-button issues of high influx of foreign workers and cost of living. Lee initiated a major re-structuring of the economy to raise productivity, improved universal healthcare and grants, especially for the pioneer generation of citizens, amongst many new inclusive measures.

 

On 23 March 2015, its founding prime minister, Lee Kuan Yew, who had 'personified Singapore to the world' for nearly half a century died. In a week of national mourning, 1.7 million residents and guests paid tribute to him at his lying-in-state at Parliament House and at community sites around the island.

 

Singapore celebrated its Golden jubilee in 2015 – its 50th year of independence, with a year-long series of events branded SG50. The PAP maintained its dominance in Parliament at the September general elections, receiving 69.9% of the popular vote, its second-highest polling result behind the 2001 tally of 75.3%.

 

GEOGRAPHY

Singapore consists of 63 islands, including the main island, Pulau Ujong. There are two man-made connections to Johor, Malaysia: the Johor–Singapore Causeway in the north and the Tuas Second Link in the west. Jurong Island, Pulau Tekong, Pulau Ubin and Sentosa are the largest of Singapore's smaller islands. The highest natural point is Bukit Timah Hill at 163.63 m. April and May are the hottest months, with the wetter monsoon season from November to January.

 

From July to October, there is often haze caused by bush fires in neighbouring Indonesia, usually from the island of Sumatra. Although Singapore does not observe daylight saving time (DST), it follows the GMT+8 time zone, one hour ahead of the typical zone for its geographical location.

 

GOVERNMENT AND POLITICS

Singapore is a parliamentary republic with a Westminster system of unicameral parliamentary government representing constituencies. The country's constitution establishes a representative democracy as the political system. Executive power rests with the Cabinet of Singapore, led by the Prime Minister and, to a much lesser extent, the President. The President is elected through a popular vote, and has veto powers over a specific set of executive decisions, such as the use of the national reserves and the appointment of judges, but otherwise occupies a largely ceremonial post.

 

The Parliament serves as the legislative branch of the government. Members of Parliament (MPs) consist of elected, non-constituency and nominated members. Elected MPs are voted into the Parliament on a "first-past-the-post" (plurality) basis and represent either single-member or group representation constituencies. The People's Action Party has won control of Parliament with large majorities in every election since self-governance was secured in 1959.

 

Although the elections are clean, there is no independent electoral authority and the government has strong influence on the media. Freedom House ranks Singapore as "partly free" in its Freedom in the World report, and The Economist ranks Singapore as a "flawed democracy", the second best rank of four, in its "Democracy Index". Despite this, in the 2011 Parliamentary elections, the opposition, led by the Workers' Party, increased its representation to seven elected MPs. In the 2015 elections, PAP scored a landslide victory, winning 83 of 89 seats contested, with 70% of popular votes. Gallup polls reported 84% of residents in Singapore expressed confidence in the government, and 85% in its judicial systems and courts – one of the highest ratings in the world.

 

Singapore's governance model eschews populist politics, focusing on the nation's long-term interest, and is known to be clean, effective and pragmatic. As a small nation highly dependent on external trade, it is vulnerable to geo-politics and global economics. It places great emphasis on security and stability of the region in its foreign policies, and applies global best practices to ensure the nation's attractiveness as an investment destination and business hub.

 

The legal system of Singapore is based on English common law, but with substantial local differences. Trial by jury was abolished in 1970 so that judicial decisions would rest entirely in the hands of appointed judges. Singapore has penalties that include judicial corporal punishment in the form of caning, which may be imposed for such offences as rape, rioting, vandalism, and certain immigration offences.There is a mandatory death penalty for murder, as well as for certain aggravated drug-trafficking and firearms offences.

 

Amnesty International has said that some legal provisions of the Singapore system conflict with the right to be presumed innocent until proven guilty, and that Singapore has "... possibly the highest execution rate in the world relative to its population". The government has disputed Amnesty's claims. In a 2008 survey of international business executives, Singapore received the top ranking with regard to judicial system quality in Asia. Singapore has been consistently rated among the least corrupt countries in the world by Transparency International.

 

In 2011, the World Justice Project's Rule of Law Index ranked Singapore among the top countries surveyed with regard to "order and security", "absence of corruption", and "effective criminal justice". However, the country received a much lower ranking for "freedom of speech" and "freedom of assembly". All public gatherings of five or more people require police permits, and protests may legally be held only at the Speakers' Corner.

 

EDUCATION

Education for primary, secondary, and tertiary levels is mostly supported by the state. All institutions, private and public, must be registered with the Ministry of Education. English is the language of instruction in all public schools, and all subjects are taught and examined in English except for the "mother tongue" language paper. While the term "mother tongue" in general refers to the first language internationally, in Singapore's education system, it is used to refer to the second language, as English is the first language. Students who have been abroad for a while, or who struggle with their "Mother Tongue" language, are allowed to take a simpler syllabus or drop the subject.

 

Education takes place in three stages: primary, secondary, and pre-university education. Only the primary level is compulsory. Students begin with six years of primary school, which is made up of a four-year foundation course and a two-year orientation stage. The curriculum is focused on the development of English, the mother tongue, mathematics, and science. Secondary school lasts from four to five years, and is divided between Special, Express, Normal (Academic), and Normal (Technical) streams in each school, depending on a student's ability level. The basic coursework breakdown is the same as in the primary level, although classes are much more specialised. Pre-university education takes place over two to three years at senior schools, mostly called Junior Colleges.

 

Some schools have a degree of freedom in their curriculum and are known as autonomous schools. These exist from the secondary education level and up.

 

National examinations are standardised across all schools, with a test taken after each stage. After the first six years of education, students take the Primary School Leaving Examination (PSLE), which determines their placement at secondary school. At the end of the secondary stage, GCE "O"-Level exams are taken; at the end of the following pre-university stage, the GCE "A"-Level exams are taken. Of all non-student Singaporeans aged 15 and above, 18% have no education qualifications at all while 45% have the PSLE as their highest qualification; 15% have the GCE 'O' Level as their highest qualification and 14% have a degree.

 

Singaporean students consistently rank at or near the top of international education assessments:

- In 2015, Singapore topped the OECD's global school performance rankings, based on 15-year-old students' average scores in mathematics and science across 76 countries.

- Singaporean students were ranked first in the 2011 Trends in International Mathematics and Science Study conducted by the International Association for the Evaluation of Educational Achievement, and have been ranked in the top three every year since 1995.

- Singapore fared best in the 2015 International Baccalaureate exams, taken in 107 countries, with more than half of the world's 81 perfect scorers and 98% passing rate.

 

The country's two main public universities - the National University of Singapore and Nanyang Technological University - are ranked among the top 13 in the world.

 

HEALTH

Singapore has a generally efficient healthcare system, even though their health expenditures are relatively low for developed countries. The World Health Organisation ranks Singapore's healthcare system as 6th overall in the world in its World Health Report. In general, Singapore has had the lowest infant mortality rate in the world for the past two decades.

 

Life expectancy in Singapore is 80 for males and 85 for females, placing the country 4th in the world for life expectancy. Almost the whole population has access to improved water and sanitation facilities. There are fewer than 10 annual deaths from HIV per 100,000 people. There is a high level of immunisation. Adult obesity is below 10%

 

The government's healthcare system is based upon the "3M" framework. This has three components: Medifund, which provides a safety net for those not able to otherwise afford healthcare, Medisave, a compulsory health savings scheme covering about 85% of the population, and Medishield, a government-funded health insurance program. Public hospitals in Singapore have autonomy in their management decisions, and compete for patients. A subsidy scheme exists for those on low income. In 2008, 32% of healthcare was funded by the government. It accounts for approximately 3.5% of Singapore's GDP.

 

RELIGION

Buddhism is the most widely practised religion in Singapore, with 33% of the resident population declaring themselves adherents at the most recent census. The next-most practised religion is Christianity, followed by Islam, Taoism, and Hinduism. 17% of the population did not have a religious affiliation. The proportion of Christians, Taoists, and non-religious people increased between 2000 and 2010 by about 3% each, whilst the proportion of Buddhists decreased. Other faiths remained largely stable in their share of the population. An analysis by the Pew Research Center found Singapore to be the world's most religiously diverse nation.

 

There are monasteries and Dharma centres from all three major traditions of Buddhism in Singapore: Theravada, Mahayana, and Vajrayana. Most Buddhists in Singapore are Chinese and are of the Mahayana tradition, with missionaries having come into the country from Taiwan and China for several decades. However, Thailand's Theravada Buddhism has seen growing popularity among the populace (not only the Chinese) during the past decade. Soka Gakkai International, a Japanese Buddhist organisation, is practised by many people in Singapore, but mostly by those of Chinese descent. Tibetan Buddhism has also made slow inroads into the country in recent years.

 

CULTURE

Singapore has one of the lowest rates of drug use in the world. Culturally, the use of illicit drugs is viewed as highly undesirable by Singaporeans, unlike many European societies. Singaporeans' disapproval towards drug use has resulted in laws that impose the mandatory death sentence for certain serious drug trafficking offences. Singapore also has a low rate of alcohol consumption per capita and low levels of violent crime, and one of the lowest intentional homicide rate globally. The average alcohol consumption rate is only 2 litres annually per adult, one of the lowest in the world.

 

Foreigners make up 42% of the population, and have a strong influence on Singaporean culture. The Economist Intelligence Unit, in its 2013 "Where-to-be-born Index", ranks Singapore as having the best quality of life in Asia and sixth overall in the world.

 

LANGUAGES; RELIGIONS AND CULTURES

Singapore is a very diverse and young country. It has many languages, religions, and cultures for a country its size.

 

When Singapore became independent from the United Kingdom in 1963, most of the newly minted Singaporean citizens were uneducated labourers from Malaysia, China and India. Many of them were transient labourers who were seeking to make some money in Singapore and they had no intention of staying permanently. A sizeable minority of middle-class, local-born people, known as the Peranakans, also existed. With the exception of the Peranakans (descendants of late 15th and 16th-century Chinese immigrants) who pledged their loyalties to Singapore, most of the labourers' loyalties lay with their respective homelands of Malaysia, China and India. After independence, the process of crafting a Singaporean identity and culture began.

 

Former Prime Ministers of Singapore, Lee Kuan Yew and Goh Chok Tong, have stated that Singapore does not fit the traditional description of a nation, calling it a society-in-transition, pointing out the fact that Singaporeans do not all speak the same language, share the same religion, or have the same customs. Even though English is the first language of the nation, according to the government's 2010 census 20% of Singaporeans, or one in five, are illiterate in English. This is a marked improvement from 1990 where 40% of Singaporeans were illiterate in English.

 

Languages, religions and cultures among Singaporeans are not delineated according to skin colour or ancestry, unlike many other countries. Among Chinese Singaporeans, one in five is Christian, another one in five is atheist, and the rest are mostly Buddhists or Taoists. One-third speak English as their home language, while half speak Mandarin Chinese. The rest speak other Chinese varieties at home. Most Malays in Singapore speak Malay as their home language with some speaking English. Singaporean Indians are much more religious. Only 1% of them are atheists. Six in ten are Hindu, two in ten Muslim, and the rest mostly Christian. Four in ten speak English as their home language, three in ten Tamil, one in ten Malay, and the rest other Indian languages as their home language.

 

Each Singaporean's behaviours and attitudes would therefore be influenced by, among many other things, his or her home language and his religion. Singaporeans who speak English as their native language tend to lean toward Western culture, while those who speak Chinese as their native language tend to lean toward Chinese culture and Confucianism. Malay speaking Singaporeans tend to lean toward the Malay culture, which itself is closely linked to the Islamic culture.

 

ATTITUDES AND BELIEFS

At the national level in Singapore, meritocracy, where one is judged based on one's ability, is heavily emphasised.

 

Racial and religious harmony is regarded by Singaporeans as a crucial part of Singapore's success, and played a part in building a Singaporean identity. Singapore has a reputation as a nanny state. The national flower of Singapore is the hybrid orchid, Vanda 'Miss Joaquim', named in memory of a Singapore-born Armenian woman, who crossbred the flower in her garden at Tanjong Pagar in 1893. Many national symbols such as the Coat of arms of Singapore and the Lion head symbol of Singapore make use of the lion, as Singapore is known as the Lion City. Other monikers by which Singapore is widely known is the Garden City and the Red Dot. Public holidays in Singapore cover major Chinese, Western, Malay and Indian festivals.

 

Singaporean employees work an average of around 45 hours weekly, relatively long compared to many other nations. Three in four Singaporean employees surveyed stated that they take pride in doing their work well, and that doing so helps their self-confidence.

 

CUISINE

Dining, along with shopping, is said to be the country's national pastime. The focus on food has led countries like Australia to attract Singaporean tourists with food-based itineraries. The diversity of food is touted as a reason to visit the country, and the variety of food representing different ethnicities is seen by the government as a symbol of its multiculturalism. The "national fruit" of Singapore is the durian.

 

In popular culture, food items belong to a particular ethnicity, with Chinese, Malay, and Indian food clearly defined. However, the diversity of cuisine has been increased further by the "hybridisation" of different styles (e.g., the Peranakan cuisine, a mix of Chinese and Malay cuisine).

 

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Patent US6506148 - Nervous system manipulation by electromagnetic fields from monitors

  

Publication number US6506148 B2

Publication type Grant

Application number US 09/872,528

Publication date Jan 14, 2003

Filing date Jun 1, 2001

Priority date Jun 1, 2001

Fee status Paid

Also published as US20020188164

 

Inventors Hendricus G. Loos

Original Assignee Hendricus G. Loos

Export Citation BiBTeX, EndNote, RefMan

Patent Citations (16), Non-Patent Citations (5), Referenced by (3), Classifications (6), Legal Events (3)

  

External Links: USPTO, USPTO Assignment, Espacenet

  

Nervous system manipulation by electromagnetic fields from monitors

US 6506148 B2

  

Abstract

  

Physiological effects have been observed in a human subject in response to stimulation of the skin with weak electromagnetic fields that are pulsed with certain frequencies near ½ Hz or 2.4 Hz, such as to excite a sensory resonance. Many computer monitors and TV tubes, when displaying pulsed images, emit pulsed electromagnetic fields of sufficient amplitudes to cause such excitation. It is therefore possible to manipulate the nervous system of a subject by pulsing images displayed on a nearby computer monitor or TV set. For the latter, the image pulsing may be imbedded in the program material, or it may be overlaid by modulating a video stream, either as an RF signal or as a video signal. The image displayed on a computer monitor may be pulsed effectively by a simple computer program. For certain monitors, pulsed electromagnetic fields capable of exciting sensory resonances in nearby subjects may be generated even as the displayed images are pulsed with subliminal intensity.

  

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Claims(14)

  

I claim:

  

1. A method for manipulating the nervous system of a subject located near a monitor, the monitor emitting an electromagnetic field when displaying an image by virtue of the physical display process, the subject having a sensory resonance frequency, the method comprising:

 

creating a video signal for displaying an image on the monitor, the image having an intensity;

 

modulating the video signal for pulsing the image intensity with a frequency in the range 0.1 Hz to 15 Hz; and

 

setting the pulse frequency to the resonance frequency.

  

2. A computer program for manipulating the nervous system of a subject located near a monitor, the monitor emitting an electromagnetic field when displaying an image by virtue of the physical display process, the subject having cutaneous nerves that fire spontaneously and have spiking patterns, the computer program comprising:

 

a display routine for displaying an image on the monitor, the image having an intensity;

 

a pulse routine for pulsing the image intensity with a frequency in the range 0.1 Hz to 15 Hz; and

 

a frequency routine that can be internally controlled by the subject, for setting the frequency;

 

whereby the emitted electromagnetic field is pulsed, the cutaneous nerves are exposed to the pulsed electromagnetic field, and the spiking patterns of the nerves acquire a frequency modulation.

  

3. The computer program of claim 2, wherein the pulsing has an amplitude and the program further comprises an amplitude routine for control of the amplitude by the subject.

  

4. The computer program of claim 2, wherein the pulse routine comprises:

 

a timing procedure for timing the pulsing; and

 

an extrapolation procedure for improving the accuracy of the timing procedure.

  

5. The computer program of claim 2, further comprising a variability routine for introducing variability in the pulsing.

  

6. Hardware means for manipulating the nervous system of a subject located near a monitor, the monitor being responsive to a video stream and emitting an electromagnetic field when displaying an image by virtue of the physical display process, the image having an intensity, the subject having cutaneous nerves that fire spontaneously and have spiking patterns, the hardware means comprising:

 

pulse generator for generating voltage pulses;

 

means, responsive to the voltage pulses, for modulating the video stream to pulse the image intensity;

 

whereby the emitted electromagnetic field is pulsed, the cutaneous nerves are exposed to the pulsed electromagnetic field, and the spiking patterns of the nerves acquire a frequency modulation.

  

7. The hardware means of claim 6, wherein the video stream is a composite video signal that has a pseudo-dc level, and the means for modulating the video stream comprise means for pulsing the pseudo-dc level.

  

8. The hardware means of claim 6, wherein the video stream is a television broadcast signal, and the means for modulating the video stream comprise means for frequency wobbling of the television broadcast signal.

  

9. The hardware means of claim 6, wherein the monitor has a brightness adjustment terminal, and the means for modulating the video stream comprise a connection from the pulse generator to the brightness adjustment terminal.

  

10. A source of video stream for manipulating the nervous system of a subject located near a monitor, the monitor emitting an electromagnetic field when displaying an image by virtue of the physical display process, the subject having cutaneous nerves that fire spontaneously and have spiking patterns, the source of video stream comprising:

 

means for defining an image on the monitor, the image having an intensity; and

 

means for subliminally pulsing the image intensity with a frequency in the range 0.1 Hz to 15 Hz;

 

whereby the emitted electromagnetic field is pulsed, the cutaneous nerves are exposed to the pulsed electromagnetic field, and the spiking patterns of the nerves acquire a frequency modulation.

  

11. The source of video stream of claim 10 wherein the source is a recording medium that has recorded data, and the means for subliminally pulsing the image intensity comprise an attribute of the recorded data.

  

12. The source of video stream of claim 10 wherein the source is a computer program, and the means for subliminally pulsing the image intensity comprise a pulse routine.

  

13. The source of video stream of claim 10 wherein the source is a recording of a physical scene, and the means for subliminally pulsing the image intensity comprise:

 

pulse generator for generating voltage pulses;

 

light source for illuminating the scene, the light source having a power level; and

 

modulation means, responsive to the voltage pulses, for pulsing the power level.

  

14. The source of video stream of claim 10, wherein the source is a DVD, the video stream comprises a luminance signal and a chrominance signal, and the means for subliminal pulsing of the image intensity comprise means for pulsing the luminance signal.

  

Description

  

BACKGROUND OF THE INVENTION

The invention relates to the stimulation of the human nervous system by an electromagnetic field applied externally to the body. A neurological effect of external electric fields has been mentioned by Wiener (1958), in a discussion of the bunching of brain waves through nonlinear interactions. The electric field was arranged to provide “a direct electrical driving of the brain”. Wiener describes the field as set up by a 10 Hz alternating voltage of 400 V applied in a room between ceiling and ground. Brennan (1992) describes in U.S. Pat. No. 5,169,380 an apparatus for alleviating disruptions in circadian rythms of a mammal, in which an alternating electric field is applied across the head of the subject by two electrodes placed a short distance from the skin.

 

A device involving a field electrode as well as a contact electrode is the “Graham Potentializer” mentioned by Hutchison (1991). This relaxation device uses motion, light and sound as well as an alternating electric field applied mainly to the head. The contact electrode is a metal bar in Ohmic contact with the bare feet of the subject, and the field electrode is a hemispherical metal headpiece placed several inches from the subject's head.

 

In these three electric stimulation methods the external electric field is applied predominantly to the head, so that electric currents are induced in the brain in the physical manner governed by electrodynamics. Such currents can be largely avoided by applying the field not to the head, but rather to skin areas away from the head. Certain cutaneous receptors may then be stimulated and they would provide a signal input into the brain along the natural pathways of afferent nerves. It has been found that, indeed, physiological effects can be induced in this manner by very weak electric fields, if they are pulsed with a frequency near ½ Hz. The observed effects include ptosis of the eyelids, relaxation, drowziness, the feeling of pressure at a centered spot on the lower edge of the brow, seeing moving patterns of dark purple and greenish yellow with the eyes closed, a tonic smile, a tense feeling in the stomach, sudden loose stool, and sexual excitement, depending on the precise frequency used, and the skin area to which the field is applied. The sharp frequency dependence suggests involvement of a resonance mechanism.

 

It has been found that the resonance can be excited not only by externally applied pulsed electric fields, as discussed in U.S. Pat. Nos. 5,782,874, 5,899,922, 6,081,744, and 6,167,304, but also by pulsed magnetic fields, as described in U.S. Pat. Nos. 5,935,054 and 6,238,333, by weak heat pulses applied to the skin, as discussed in U.S. Pat. Nos. 5,800,481 and 6,091,994, and by subliminal acoustic pulses, as described in U.S. Pat. No. 6,017,302. Since the resonance is excited through sensory pathways, it is called a sensory resonance. In addition to the resonance near ½ Hz, a sensory resonance has been found near 2.4 Hz. The latter is characterized by the slowing of certain cortical processes, as discussed in the '481, '922, '302, '744, '944, and '304 patents.

 

The excitation of sensory resonances through weak heat pulses applied to the skin provides a clue about what is going on neurologically. Cutaneous temperature-sensing receptors are known to fire spontaneously. These nerves spike somewhat randomly around an average rate that depends on skin temperature. Weak heat pulses delivered to the skin in periodic fashion will therefore cause a slight frequency modulation (fm) in the spike patterns generated by the nerves. Since stimulation through other sensory modalities results in similar physiological effects, it is believed that frequency modulation of spontaneous afferent neural spiking patterns occurs there as well.

 

It is instructive to apply this notion to the stimulation by weak electric field pulses administered to the skin. The externally generated fields induce electric current pulses in the underlying tissue, but the current density is much too small for firing an otherwise quiescent nerve. However, in experiments with adapting stretch receptors of the crayfish, Terzuolo and Bullock (1956) have observed that very small electric fields can suffice for modulating the firing of already active nerves. Such a modulation may occur in the electric field stimulation under discussion.

 

Further understanding may be gained by considering the electric charges that accumulate on the skin as a result of the induced tissue currents. Ignoring thermodynamics, one would expect the accumulated polarization charges to be confined strictly to the outer surface of the skin. But charge density is caused by a slight excess in positive or negative ions, and thermal motion distributes the ions through a thin layer. This implies that the externally applied electric field actually penetrates a short distance into the tissue, instead of stopping abruptly at the outer skin surface. In this manner a considerable fraction of the applied field may be brought to bear on some cutaneous nerve endings, so that a slight modulation of the type noted by Terzuolo and Bullock may indeed occur.

 

The mentioned physiological effects are observed only when the strength of the electric field on the skin lies in a certain range, called the effective intensity window. There also is a bulk effect, in that weaker fields suffice when the field is applied to a larger skin area. These effects are discussed in detail in the '922 patent.

 

Since the spontaneous spiking of the nerves is rather random and the frequency modulation induced by the pulsed field is very shallow, the signal to noise ratio (S/N) for the fm signal contained in the spike trains along the afferent nerves is so small as to make recovery of the fm signal from a single nerve fiber impossibile. But application of the field over a large skin area causes simultaneous stimulation of many cutaneous nerves, and the fm modulation is then coherent from nerve to nerve. Therefore, if the afferent signals are somehow summed in the brain, the fm modulations add while the spikes from different nerves mix and interlace. In this manner the S/N can be increased by appropriate neural processing. The matter is discussed in detail in the '874 patent. Another increase in sensitivity is due to involving a resonance mechanism, wherein considerable neural circuit oscillations can result from weak excitations.

 

An easily detectable physiological effect of an excited ½ Hz sensory resonance is ptosis of the eyelids. As discussed in the '922 patent, the ptosis test involves first closing the eyes about half way. Holding this eyelid position, the eyes are rolled upward, while giving up voluntary control of the eyelids. The eyelid position is then determined by the state of the autonomic nervous system. Furthermore, the pressure excerted on the eyeballs by the partially closed eyelids increases parasympathetic activity. The eyelid position thereby becomes somewhat labile, as manifested by a slight flutter. The labile state is sensitive to very small shifts in autonomic state. The ptosis influences the extent to which the pupil is hooded by the eyelid, and thus how much light is admitted to the eye. Hence, the depth of the ptosis is seen by the subject, and can be graded on a scale from 0 to 10.

 

In the initial stages of the excitation of the ½ Hz sensory resonance, a downward drift is detected in the ptosis frequency, defined as the stimulation frequency for which maximum ptosis is obtained. This drift is believed to be caused by changes in the chemical milieu of the resonating neural circuits. It is thought that the resonance causes perturbations of chemical concentrations somewhere in the brain, and that these perturbations spread by diffusion to nearby resonating circuits. This effect, called “chemical detuning”, can be so strong that ptosis is lost altogether when the stimulation frequency is kept constant in the initial stages of the excitation. Since the stimulation then falls somewhat out of tune, the resonance decreases in amplitude and chemical detuning eventually diminishes. This causes the ptosis frequency to shift back up, so that the stimulation is more in tune and the ptosis can develop again. As a result, for fixed stimulation frequencies in a certain range, the ptosis slowly cycles with a frequency of several minutes. The matter is discussed in the '302 patent.

 

The stimulation frequencies at which specific physiological effects occur depend somewhat on the autonomic nervous system state, and probably on the endocrine state as well.

 

Weak magnetic fields that are pulsed with a sensory resonance frequency can induce the same physiological effects as pulsed electric fields. Unlike the latter however, the magnetic fields penetrate biological tissue with nearly undiminished strength. Eddy currents in the tissue drive electric charges to the skin, where the charge distributions are subject to thermal smearing in much the same way as in electric field stimulation, so that the same physiological effects develop. Details are discussed in the '054 patent.

SUMMARY

Computer monotors and TV monitors can be made to emit weak low-frequency electromagnetic fields merely by pulsing the intensity of displayed images. Experiments have shown that the ½ Hz sensory resonance can be excited in this manner in a subject near the monitor. The 2.4 Hz sensory resonance can also be excited in this fashion. Hence, a TV monitor or computer monitor can be used to manipulate the nervous system of nearby people.

 

The implementations of the invention are adapted to the source of video stream that drives the monitor, be it a computer program, a TV broadcast, a video tape or a digital video disc (DVD).

 

For a computer monitor, the image pulses can be produced by a suitable computer program. The pulse frequency may be controlled through keyboard input, so that the subject can tune to an individual sensory resonance frequency. The pulse amplitude can be controlled as well in this manner. A program written in Visual Basic(R) is particularly suitable for use on computers that run the Windows 95(R) or Windows 98(R) operating system. The structure of such a program is described. Production of periodic pulses requires an accurate timing procedure. Such a procedure is constructed from the GetTimeCount function available in the Application Program Interface (API) of the Windows operating system, together with an extrapolation procedure that improves the timing accuracy.

 

Pulse variability can be introduced through software, for the purpose of thwarting habituation of the nervous system to the field stimulation, or when the precise resonance frequency is not known. The variability may be a pseudo-random variation within a narrow interval, or it can take the form of a frequency or amplitude sweep in time. The pulse variability may be under control of the subject.

 

The program that causes a monitor to display a pulsing image may be run on a remote computer that is connected to the user computer by a link; the latter may partly belong to a network, which may be the Internet.

 

For a TV monitor, the image pulsing may be inherent in the video stream as it flows from the video source, or else the stream may be modulated such as to overlay the pulsing. In the first case, a live TV broadcast can be arranged to have the feature imbedded simply by slightly pulsing the illumination of the scene that is being broadcast. This method can of course also be used in making movies and recording video tapes and DVDs.

 

Video tapes can be edited such as to overlay the pulsing by means of modulating hardware. A simple modulator is discussed wherein the luminance signal of composite video is pulsed without affecting the chroma signal. The same effect may be introduced at the consumer end, by modulating the video stream that is produced by the video source. A DVD can be edited through software, by introducing pulse-like variations in the digital RGB signals. Image intensity pulses can be overlaid onto the analog component video output of a DVD player by modulating the luminance signal component. Before entering the TV set, a television signal can be modulated such as to cause pulsing of the image intensity by means of a variable delay line that is connected to a pulse generator.

 

Certain monitors can emit electromagnetic field pulses that excite a sensory resonance in a nearby subject, through image pulses that are so weak as to be subliminal. This is unfortunate since it opens a way for mischievous application of the invention, whereby people are exposed unknowingly to manipulation of their nervous systems for someone else's purposes. Such application would be unethical and is of course not advocated. It is mentioned here in order to alert the public to the possibility of covert abuse that may occur while being online, or while watching TV, a video, or a DVD.

DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates the electromagnetic field that emanates from a monitor when the video signal is modulated such as to cause pulses in image intensity, and a nearby subject who is exposed to the field.

 

FIG. 2 shows a circuit for modulation of a composite video signal for the purpose of pulsing the image intensity.

 

FIG. 3 shows the circuit for a simple pulse generator.

 

FIG. 4 illustrates how a pulsed electromagnetic field can be generated with a computer monitor.

 

FIG. 5 shows a pulsed electromagnetic field that is generated by a television set through modulation of the RF signal input to the TV.

 

FIG. 6 outlines the structure of a computer program for producing a pulsed image.

 

FIG. 7 shows an extrapolation procedure introduced for improving timing accuracy of the program of FIG. 6.

 

FIG. 8 illustrates the action of the extrapolation procedure of FIG. 7.

 

FIG. 9 shows a subject exposed to a pulsed electromagnetic field emanating from a monitor which is responsive to a program running on a remote computer via a link that involves the Internet.

 

FIG. 10 shows the block diagram of a circuit for frequency wobbling of a TV signal for the purpose of pulsing the intensity of the image displayed on a TV monitor.

 

FIG. 11 depicts schematically a recording medium in the form of a video tape with recorded data, and the attribute of the signal that causes the intensity of the displayed image to be pulsed.

 

FIG. 12 illustrates how image pulsing can be embedded in a video signal by pulsing the illumination of the scene that is being recorded.

 

FIG. 13 shows a routine that introduces pulse variability into the computer program of FIG. 6.

 

FIG. 14 shows schematically how a CRT emits an electromagnetic field when the displayed image is pulsed.

 

FIG. 15 shows how the intensity of the image displayed on a monitor can be pulsed through the brightness control terminal of the monitor.

 

FIG. 16 illustrates the action of the polarization disc that serves as a model for grounded conductors in the back of a CRT screen.

 

FIG. 17 shows the circuit for overlaying image intensity pulses on a DVD output.

 

FIG. 18 shows measured data for pulsed electric fields emitted by two different CRT type monitors, and a comparison with theory.

DETAILED DESCRIPTION

Computer monitors and TV monitors emit electromagnetic fields. Part of the emission occurs at the low frequencies at which displayed images are changing. For instance, a rythmic pulsing of the intensity of an image causes electromagnetic field emission at the pulse frequency, with a strength proportional to the pulse amplitude. The field is briefly referred to as “screen emission”. In discussing this effect, any part or all what is displayed on the monitor screen is called an image. A monitor of the cathode ray tube (CRT) type has three electron beams, one for each of the basic colors red, green, and blue. The intensity of an image is here defined as

 

I=∫j dA,  (1)

 

where the integral extends over the image, and

 

j=jr+jg+jb,  (2)

 

jr, jg, and jb being the electric current densities in the red, green, and blue electron beams at the surface area dA of the image on the screen. The current densities are to be taken in the distributed electron beam model, where the discreteness of pixels and the raster motion of the beams are ignored, and the back of the monitor screen is thought to be irradiated by diffuse electron beams. The beam current densities are then functions of the coordinates x and y over the screen. The model is appropriate since we are interested in the electromagnetic field emision caused by image pulsing with the very low frequencies of sensory resonances, whereas the emissions with the much higher horizontal and vertical sweep frequencies are of no concern. For a CRT the intensity of an image is expressed in millamperes.

 

For a liquid crystal display (LCD), the current densities in the definition of image intensity are to be replaced by driving voltages, multiplied by the aperture ratio of the device. For an LCD, image intensities are thus expressed in volts.

 

It will be shown that for a CRT or LCD screen emissions are caused by fluctuations in image intensity. In composite video however, intensity as defined above is not a primary signal feature, but luminance Y is. For any pixel one has

 

Y=0.299R+0.587G+0.114B,  (3)

 

where R, G, and B are the intensities of the pixel respectively in red, green and blue, normalized such as to range from 0 to 1. The definition (3) was provided by the Commission Internationale de l'Eclairage (CIE), in order to account for brightness differences at different colors, as perceived by the human visual system. In composite video the hue of the pixel is determined by the chroma signal or chrominance, which has the components R-Y and B-Y It follows that pulsing pixel luminance while keeping the hue fixed is equivalent to pulsing the pixel intensity, up to an amplitude factor. This fact will be relied upon when modulating a video stream such as to overlay image intensity pulses.

 

It turns out that the screen emission has a multipole expansion wherein both monopole and dipole contributions are proportional to the rate of change of the intensity I of (1). The higher order multipole contributions are proportional to the rate of change of moments of the current density j over the image, but since these contributions fall off rapidly with distance, they are not of practical importance in the present context. Pulsing the intensity of an image may involve different pulse amplitudes, frequencies, or phases for different parts of the image. Any or all of these features may be under subject control.

 

The question arises whether the screen emission can be strong enough to excite sensory resonances in people located at normal viewing distances from the monitor. This turns out to be the case, as shown by sensory resonance experiments and independently by measuring the strength of the emitted electric field pulses and comparing the results with the effective intensity window as explored in earlier work.

 

One-half Hertz sensory resonance experiments have been conducted with the subject positioned at least at normal viewing distance from a 15″ computer monitor that was driven by a computer program written in Visual Basic(R), version 6.0 (VB6). The program produces a pulsed image with uniform luminance and hue over the full screen, except for a few small control buttons and text boxes. In VB6, screen pixel colors are determined by integers R, G, and B, that range from 0 to 255, and set the contributions to the pixel color made by the basic colors red, green, and blue. For a CRT-type monitor, the pixel intensities for the primary colors may depend on the RGB values in a nonlinear manner that will be discussed. In the VB6 program the RGB values are modulated by small pulses ΔR, ΔG, ΔB, with a frequency that can be chosen by the subject or is swept in a predetermined manner. In the sensory resonance experiments mentioned above, the ratios ΔR/R, ΔG/G, and ΔB/B were always smaller than 0.02, so that the image pulses are quite weak. For certain frequencies near ½ Hz, the subject experienced physiological effects that are known to accompany the excitation of the ½ Hz sensory resonance as mentioned in the Background Section. Moreover, the measured field pulse amplitudes fall within the effective intensity window for the ½ Hz resonance, as explored in earlier experiments and discussed in the '874, '744, '922, and '304 patents. Other experiments have shown that the 2.4 Hz sensory resonance can be exited as well by screen emissions from monitors that display pulsed images.

 

These results confirm that, indeed, the nervous system of a subject can be manipulated through electromagnetic field pulses emitted by a nearby CRT or LCD monitor which displays images with pulsed intensity.

 

The various implementations of the invention are adapted to the different sources of video stream, such as video tape, DVD, a computer program, or a TV broadcast through free space or cable. In all of these implementations, the subject is exposed to the pulsed electromagnetic field that is generated by the monitor as the result of image intensity pulsing. Certain cutaneous nerves of the subject exhibit spontaneous spiking in patterns which, although rather random, contain sensory information at least in the form of average frequency. Some of these nerves have receptors that respond to the field stimulation by changing their average spiking frequency, so that the spiking patterns of these nerves acquire a frequency modulation, which is conveyed to the brain. The modulation can be particularly effective if it has a frequency at or near a sensory resonance frequency. Such frequencies are expected to lie in the range from 0.1 to 15 Hz.

 

An embodiment of the invention adapted to a VCR is shown in FIG. 1, where a subject 4 is exposed to a pulsed electric field 3 and a pulsed magnetic field 39 that are emitted by a monitor 2, labeled “MON”, as the result of pulsing the intensity of the displayed image. The image is here generated by a video casette recorder 1, labeled “VCR”, and the pulsing of the image intensity is obtained by modulating the composite video signal from the VCR output. This is done by a video modulator 5, labeled “VM”, which responds to the signal from the pulse generator 6, labeled “GEN”. The frequency and amplitude of the image pulses can be adjusted with the frequency control 7 and amplitude control 8. Frequency and amplitude adjustments can be made by the subject.

 

The circuit of the video modulator 5 of FIG. 1 is shown in FIG. 2, where the video amplifiers 11 and 12 process the composite video signal that enters at the input terminal 13. The level of the video signal is modulated slowly by injecting a small bias current at the inverting input 17 of the first amplifier 11. This current is caused by voltage pulses supplied at the modulation input 16, and can be adjusted through the potentiometer 15. Since the noninverting input of the amplifier is grounded, the inverting input 17 is kept essentially at ground potential, so that the bias current is is not influenced by the video signal. The inversion of the signal by the first amplifier 11 is undone by the second amplifier 12. The gains of the amplifiers are chosen such as to give a unity overall gain. A slowly varying current injected at the inverting input 17 causes a slow shift in the “pseudo-dc” level of the composite video signal, here defined as the short-term average of the signal. Since the pseudo-dc level of the chroma signal section determines the luminance, the latter is modulated by the injected current pulses. The chroma signal is not affected by the slow modulation of the pseudodc level, since that signal is determined by the amplitude and phase with respect to the color carrier which is locked to the color burst. The effect on the sync pulses and color bursts is of no consequence either if the injected current pulses are very small, as they are in practice. The modulated composite video signal, available at the output 14 in FIG. 2, will thus exhibit a modulated luminance, whereas the chroma signal is unchanged. In the light of the foregoing discussion about luminance and intensity, it follows that the modulator of FIG. 2 causes a pulsing of the image intensity I. It remains to give an example how the pulse signal at the modulation input 16 may be obtained. FIG. 3 shows a pulse generator that is suitable for this purpose, wherein the RC timer 21 (Intersil ICM7555) is hooked up for astable operation and produces a square wave voltage with a frequency that is determined by capacitor 22 and potentiometer 23. The timer 21 is powered by a battery 26, controlled by the switch 27. The square wave voltage at output 25 drives the LED 24, which may be used for monitoring of the pulse frequency, and also serves as power indicator. The pulse output may be rounded in ways that are well known in the art. In the setup of FIG. 1, the output of VCR 1 is connected to the video input 13 of FIG. 2, and the video output 14 is connected to the monitor 2 of FIG. 1.

 

In the preferred embodiment of the invention, the image intensity pulsing is caused by a computer program. As shown in FIG. 4, monitor 2, labeled “MON”, is connected to computer 31 labeled “COMPUTER”, which runs a program that produces an image on the monitor and causes the image intensity to be pulsed. The subject 4 can provide input to the computer through the keyboard 32 that is connected to the computer by the connection 33. This input may involve adjustments of the frequency or the amplitude or the variability of the image intensity pulses. In particular, the pulse frequency can be set to a sensory resonance frequency of the subject for the purpose of exciting the resonance.

 

The structure of a computer program for pulsing image intensity is shown in FIG. 6. The program may be written in Visual Basic(R) version 6.0 (VB6), which involves the graphics interface familiar from the Windows(R) operating system. The images appear as forms equipped with user controls such as command buttons and scroll bars, together with data displays such as text boxes. A compiled VB6 program is an executable file. When activated, the program declares variables and functions to be called from a dynamic link library (DLL) that is attached to the operating system; an initial form load is performed as well. The latter comprises setting the screen color as specified by integers R, G, and B in the range 0 to 255, as mentioned above. In FIG. 6, the initial setting of the screen color is labeled as 50. Another action of the form load routine is the computation 51 of the sine function at eight equally spaced points, I=0 to 7, around the unit circle. These values are needed when modulating the RGB numbers. Unfortunately, the sine function is distorted by the rounding to integer RGB values that occurs in the VB6 program. The image is chosen to fill as much of the screen area as possible, and it has spatially uniform luminance and hue.

 

The form appearing on the monitor displays a command button for starting and stopping the image pulsing, together with scroll bars 52 and 53 respectively for adjustment of the pulse frequency F and the pulse amplitude A. These pulses could be initiated by a system timer which is activated upon the elapse of a preset time interval. However, timers in VB6 are too inaccurate for the purpose of providing the eight RGB adjustment points in each pulse cycle. An improvement can be obtained by using the GetTickCount function that is available in the Application Program Interface (API) of Windows 95(R) and Windows 98(R). The GetTickCount function returns the system time that has elapsed since starting Windows, expressed in milliseconds. User activation of the start button 54 provides a tick count TN through request 55 and sets the timer interval to TT miliseconds, in step 56. TT was previously calculated in the frequency routine that is activated by changing the frequency, denoted as step 52.

 

Since VB6 is an event-driven program, the flow chart for the program falls into disjoint pieces. Upon setting the timer interval to TT in step 56, the timer runs in the background while the program may execute subroutines such as adjustment of pulse frequency or amplitude. Upon elapse of the timer interval TT, the timer subroutine 57 starts execution with request 58 for a tick count, and in 59 an upgrade is computed of the time TN for the next point at which the RGB values are to be adjusted. In step 59 the timer is turned off, to be reactivated later in step 67. Step 59 also resets the parameter CR which plays a role in the extrapolation procedure 61 and the condition 60. For ease of understanding at this point, it is best to pretend that the action of 61 is simply to get a tick count, and to consider the loop controled by condition 60 while keeping CR equal to zero. The loop would terminate when the tick count M reaches or exceeds the time TN for the next phase point, at which time the program should adjust the image intensity through steps 63-65. For now step 62 is to be ignored also, since it has to do with the actual extrapolation procedure 61. The increments to the screen colors R1, G1, and B1 at the new phase point are computed according to the sine function, applied with the amplitude A that was set by the user in step 53. The number I that labels the phase point is incremented by unity in step 65, but if this results in I=8 the value is reset to zero in 66. Finally, the timer is reactivated in step 67, initiating a new ⅛-cycle step in the periodic progression of RGB adjustments.

 

A program written in this way would exhibit a large jitter in the times at which the RGB values are changed. This is due to the lumpiness in the tick counts returned by the GetTickCount function. The lumpiness may be studied separately by running a simple loop with C=GetTickCount, followed by writing the result C to a file. Inspection shows that C has jumped every 14 or 15 milliseconds, between long stretches of constant values. Since for a ½ Hz image intensity modulation the ⅛-cycle phase points are 250 ms apart, the lumpiness of 14 or 15 ms in the tick count would cause considerable inaccuracy. The full extrapolation procedure 61 is introduced in order to diminish the jitter to acceptable levels. The procedure works by refining the heavy-line staircase function shown in FIG. 8, using the slope RR of a recent staircase step to accurately determine the loop count 89 at which the loop controled by 60 needs to be exited. Details of the extrapolation procedure are shown in FIG. 7 and illustrated in FIG. 8. The procedure starts at 70 with both flags off, and CR=0, because of the assignment in 59 or 62 in FIG. 6. A tick count M is obtained at 71, and the remaining time MR to the next phase point is computed in 72. Conditions 77 and 73 are not satisfied and therefore passed vertically in the flow chart, so that only the delay block 74 and the assignments 75 are executed. Condition 60 of FIG. 6 is checked and found to be satisfied, so that the extrapolation procedure is reentered. The process is repeated until the condition 73 is met when the remaining time MR jumps down through the 15 ms level, shown in FIG. 8 as the transition 83. The condition 73 then directs the logic flow to the assignments 76, in which the number DM labeled by 83 is computed, and FLG1 is set. The computation of DM is required for finding the slope RR of the straight-line element 85. One also needs the “Final LM” 86, which is the number of loops traversed from step 83 to the next downward step 84, here shown to cross the MR=0 axis. The final LM is determined after repeatedly incrementing LM through the side loop entered from the FLG1=1 condition 77, which is now satisfied since FLG1 was set in step 76. At the transition 84 the condition 78 is met, so that the assignments 79 are executed. This includes computation of the slope RR of the line element 85, setting FLG2, and resetting FLG1. From here on, the extrapolation procedure increments CR in steps of RR while skipping tick counts until condition 60 of FIG. 6 is violated, the loop is exited, and the RGB values are adjusted.

 

A delay block 74 is used in order to stretch the time required for traversing the extrapolation procedure. The block can be any computation intensive subroutine such as repeated calculations of tangent and arc tangent functions.

 

As shown in step 56 of FIG. 6, the timer interval TT is set to 4/10 of the time TA from one RGB adjustment point to the next. Since the timer runs in the background, this arrangement provides an opportunity for execution of other processes such as user adjustment of frequency or amplitude of the pulses.

 

The adjustment of the frequency and other pulse parameters of the image intensity modulation can be made internally, i.e., within the running program. Such internal control is to be distinguished from the external control provided, for instance, in screen savers. In the latter, the frequency of animation can be modified by the user, but only after having exited the screen saver program. Specifically, in Windows 95(R) or Windows 98(R), to change the animation frequency requires stopping the screen saver execution by moving the mouse, whereafter the frequency may be adjusted through the control panel. The requirement that the control be internal sets the present program apart from so-called banners as well.

 

The program may be run on a remote computer that is linked to the user computer, as illustrated in FIG. 9. Although the monitor 2, labeled “MON”, is connected to the computer 31′, labeled “COMPUTER”, the program that pulses the images on the monitor 2 runs on the remoter computer 90, labeled “REMOTE COMPUTER”, which is connected to computer 31′ through a link 91 which may in part belong to a network. The network may comprise the Internet 92.

 

The monitor of a television set emits an electromagnetic field in much the same way as a computer monitor. Hence, a TV may be used to produce screen emissions for the purpose of nervous system manipulation. FIG. 5 shows such an arrangement, where the pulsing of the image intensity is achieved by inducing a small slowly pulsing shift in the frequency of the RF signal that enters from the antenna. This process is here called “frequency wobbling” of the RF signal. In FM TV, a slight slow frequency wobble of the RF signal produces a pseudo-dc signal level fluctuation in the composite video signal, which in turn causes a slight intensity fluctuation of the image displayed on the monitor in the same manner as discussed above for the modulator of FIG. 2. The frequency wobbling is induced by the wobbler 44 of FIG. 5 labeled “RFM”, which is placed in the antenna line 43. The wobbler is driven by the pulse generator 6, labeled “GEN”. The subject can adjust the frequency and the amplitude of the wobble through the tuning control 7 and the amplitude control 41. FIG. 10 shows a block diagram of the frequency wobbler circuit that employs a variable delay line 94, labelled “VDL”. The delay is determined by the signal from pulse generator 6, labelled “GEN”. The frequency of the pulses can be adjusted with the tuning control 7. The amplitude of the pulses is determined by the unit 98, labelled “MD”, and can be adjusted with the amplitude control 41. Optionally, the input to the delay line may be routed through a preprocessor 93, labelled “PRP”, which may comprise a selective RF amplifier and down converter; a complimentary up conversion should then be performed on the delay line output by a postprocessor 95, labelled “POP”. The output 97 is to be connected to the antenna terminal of the TV set.

 

The action of the variable delay line 94 may be understood as follows. Let periodic pulses with period L be presented at the input. For a fixed delay the pulses would emerge at the output with the same period L. Actually, the time delay T is varied slowly, so that it increases approximately by LdT/dt between the emergence of consecutive pulses at the device output. The pulse period is thus increased approximately by

 

ΔL=LdT/dt.  (4)

 

In terms of the frequency ∫, Eq. (4) implies approximately

 

Δ∫/∫=−dT/dt.  (5)

 

For sinusoidal delay T(t) with amplitude b and frequency g, one has

 

Δ∫/∫=−2πgb cos (2πgt),  (6)

 

which shows the frequency wobbling. The approximation is good for gb<<1, which is satisfied in practice. The relative frequency shift amplitude 2πgb that is required for effective image intensity pulses is very small compared to unity. For a pulse frequency g of the order of 1 Hz, the delay may have to be of the order of a millisecond. To accomodate such long delay values, the delay line may have to be implemented as a digital device. To do so is well within the present art. In that case it is natural to also choose digital implementations for the pulse generator 6 and the pulse amplitude controller 98, either as hardware or as software.

 

Pulse variability may be introduced for alleviating the need for precise tuning to a resonance frequency. This may be important when sensory resonance frequencies are not precisely known, because of the variation among individuals, or in order to cope with the frequency drift that results from chemical detuning that is discussed in the '874 patent. A field with suitably chosen pulse variability can then be more effective than a fixed frequency field that is out of tune. One may also control tremors and seizures, by interfering with the pathological oscillatory activity of neural circuits that occurs in these disorders. Electromagnetic fields with a pulse variability that results in a narrow spectrum of frequencies around the frequency of the pathological oscillatory activity may then evoke nerve signals that cause phase shifts which diminish or quench the oscillatory activity.

 

Pulse variability can be introduced as hardware in the manner described in the '304 patent. The variability may also be introduced in the computer program of FIG. 6, by setting FLG3 in step 68, and choosing the amplitude B of the frequency fluctuation. In the variability routine 46, shown in some detail in FIG. 13, FLG3 is detected in step 47, whereupon in steps 48 and 49 the pulse frequency F is modified pseudo randomly by a term proportional to B, every 4th cycle. Optionally, the amplitude of the image intensity pulsing may be modified as well, in similar fashion. Alternatively, the frequency and amplitude may be swept through an adjustable ramp, or according to any suitable schedule, in a manner known to those skilled in the art. The pulse variability may be applied to subliminal image intensity pulses.

 

When an image is displayed by a TV monitor in response to a TV broadcast, intensity pulses of the image may simply be imbedded in the program material. If the source of video signal is a recording medium, the means for pulsing the image intensity may comprise an attribute of recorded data. The pulsing may be subliminal. For the case of a video signal from a VCR, the pertinent data attribute is illustrated in FIG. 11, which shows a video signal record on part of a video tape 28. Depicted schematically are segments of the video signal in intervals belonging to lines in three image frames at different places along the tape. In each segment, the chroma signal 9 is shown, with its short-term average level 29 represented as a dashed line. The short-term average signal level, also called the pseudo-dc level, represents the luminance of the image pixels. Over each segment, the level is here constant because the image is for simplicity chosen as having a uniform luminance over the screen. However, the level is seen to vary from frame to frame, illustrating a luminance that pulses slowly over time. This is shown in the lower portion of the drawing, wherein the IRE level of the short-term chroma signal average is plotted versus time. The graph further shows a gradual decrease of pulse amplitude in time, illustrating that luminance pulse amplitude variations may also be an attribute of the recorded data on the video tape. As discussed, pulsing the luminance for fixed chrominance results in pulsing of the image intensity.

 

Data stream attributes that represent image intensity pulses on video tape or in TV signals may be created when producing a video rendition or making a moving picture of a scene, simply by pulsing the illumination of the scene. This is illustrated in FIG. 12, which shows a scene 19 that is recorded with a video camera 18, labelled “VR”. The scene is illuminated with a lamp 20, labelled “LAMP”, energized by an electric current through a cable 36. The current is modulated in pulsing fashion by a modulator 30, labeled “MOD”, which is driven by a pulse generator 6, labelled “GENERATOR”, that produces voltage pulses 35. Again, pulsing the luminance but not the chrominance amounts to pulsing the image intensity.

 

The brightness of monitors can usually be adjusted by a control, which may be addressable through a brightness adjustment terminal. If the control is of the analog type, the displayed image intensity may be pulsed as shown in FIG. 15, simply by a pulse generator 6, labeled “GEN”, that is connected to the brigthness adjustment terminal 88 of the monitor 2, labeled “MON”. Equivalent action can be provided for digital brightness controls, in ways that are well known in the art.

 

The analog component video signal from a DVD player may be modulated such as to overlay image intensity pulses in the manner illustrated in FIG. 17. Shown are a DVD player 102, labeled “DVD”, with analog component video output comprised of the luminance Y and chrominance C. The overlay is accomplished simply by shifting the luminance with a voltage pulse from generator 6, labeled “GENERATOR”. The generator output is applied to modulator 106, labeled “SHIFTER”. Since the luminance Y is pulsed without changing the chrominance C, the image intensity is pulsed. The frequency and amplitude of the image intensity pulses can be adjusted respectively with the tuner 7 and amplitude control 107. The modulator 105 has the same structure as the modulator of FIG. 2, and the pulse amplitude control 107 operates the potentiometer 15 of FIG. 2. The same procedure can be followed for editing a DVD such as to overlay image intensity pulses, by processing the modulated luminance signal through an analog-to-digital converter, and recording the resulting digital stream onto a DVD, after appropriate compression. Alternatively, the digital luminance data can be edited by electronic reading of the signal, decompression, altering the digital data by software, and recording the resulting digital signal after proper compression, all in a manner that is well known in the art.

 

The mechanism whereby a CRT-type monitor emits a pulsed electromagnetic field when pulsing the intensity of an image is illustrated in FIG. 14. The image is produced by an electron beam 10 which impinges upon the backside 88 of the screen, where the collisions excite phosphors that subsequently emit light. In the process, the electron beam deposits electrons 18 on the screen, and these electrons contribute to an electric field 3 labelled “E”. The electrons flow along the conductive backside 88 of the screen to the terminal 99 which is hooked up to the high-voltage supply 40, labelled “HV”. The circuit is completed by the ground connection of the supply, the video amplifier 87, labeled “VA”, and its connection to the cathodes of the CRT. The electron beams of the three electron guns are collectively shown as 10, and together the beams carry a current J. The electric current J flowing through the described circuit induces a magnetic field 39, labeled “B”. Actually, there are a multitude of circuits along which the electron beam current is returned to the CRT cathodes, since on a macroscopic scale the conductive back surface 88 of the screen provides a continuum of paths from the beam impact point to the high-voltage terminal 99. The magnetic fields induced by the currents along these paths partially cancel each other, and the resulting field depends on the location of the pixel that is addressed. Since the beams sweep over the screen through a raster of horizontal lines, the spectrum of the induced magnetic field contains strong peaks at the horizontal and vertical frequencies. However, the interest here is not in fields at those frequencies, but rather in emissions that result from an image pulsing with the very low frequencies appropriate to sensory resonances. For this purpose a diffuse electron current model suffices, in which the pixel discreteness and the raster motion of the electron beams are ignored, so that the beam current becomes diffuse and fills the cone subtended by the displayed image. The resulting low-frequency magnetic field depends on the temporal changes in the intensity distribution over the displayed image. Order-of-magnitude estimates show that the low-frequency magnetic field, although quite small, may be sufficient for the excitation of sensory resonances in subjects located at a normal viewing distance from the monitor.

 

The monitor also emits a low-frequency electric field at the image pulsing frequency. This field is due in part to the electrons 18 that are deposited on the screen by the electron beams 10. In the diffuse electron beam model, screen conditions are considered functions of the time t and of the Cartesian coordinates x and y over a flat CRT screen.

 

The screen electrons 18 that are dumped onto the back of the screen by the sum j(x,y,t) of the diffuse current distributions in the red, green, and blue electron beams cause a potential distribution V(x,y,t) which is influenced by the surface conductivity σ on the back of the screen and by capacitances. In the simple model where the screen has a capacitance distribution c(x,y) to ground and mutual capacitances between parts of the screen at different potentials are neglected, a potential distribution V(x,y,t) over the screen implies a surface charge density distribution

 

q=Vc(x,y),  (7)

 

and gives rise to a current density vector along the screen,

 

j s=−σgrads V,  (8)

 

where grads is the gradient along the screen surface. Conservation of electric charge implies

 

j=c{dot over (V)}−div s (σgrad s V),  (9)

 

where the dot over the voltage denotes the time derivative, and divs is the divergence in the screen surface. The partial differential equation (9) requires a boundary condition for the solution V(x,y,t) to be unique. Such a condition is provided by setting the potential at the rim of the screen equal to the fixed anode voltage. This is a good approximation, since the resistance Rr between the screen rim and the anode terminal is chosen small in CRT design, in order to keep the voltage loss JRr to a minimum, and also to limit low-frequency emissions.

 

Something useful can be learned from special cases with simple solutions. As such, consider a circular CRT screen of radius R with uniform conductivity, showered in the back by a diffuse electron beam with a spatially uniform beam current density that is a constant plus a sinusoidal part with frequency ∫. Since the problem is linear, the voltage V due to the sinusoidal part of the beam current can be considered separately, with the boundary condition that V vanish at the rim of the circular screen. Eq. (9) then simplifies to

 

V″+V″/r−i2π∫cn V=−Jη/A, r≦R,  (10)

 

where r is a radial coordinate along the screen with its derivative denoted by a prime, η=1/σ is the screen resistivity, A the screen area, J the sinusoidal part of the total beam current, and i=(−1), the imaginary unit. Our interest is in very low pulse frequencies ∫ that are suitable for excitation of sensory resonances. For those frequencies and for practical ranges for c and η, the dimensionless number 2π∫cAη is very much smaller than unity, so that it can be neglected in Eq. (10). The boundary value problem then has the simple solution V  ( r ) = J     η 4  π  ( 1 - ( r / R ) 2 ) . ( 11 )

Figure US06506148-20030114-M00001

 

In deriving (11) we neglected the mutual capacitance between parts of the screen that are at different potentials. The resulting error in (10) is negligible for the same reason that the i2π∫cAη term in (10) can be neglected.

 

The potential distribution V(r) of (11) along the screen is of course accompanied by electric charges. The field lines emanating from these charges run mainly to conductors behind the screen that belong to the CRT structure and that are either grounded or connected to circuitry with a low impedance path to ground. In either case the mentioned conductors must be considered grounded in the analysis of charges and fields that result from the pulsed component J of the total electron beam current. The described electric field lines end up in electric charges that may be called polarization charges since they are the result of the polarization of the conductors and circuitry by the screen emission. To estimate the pulsed electric field, a model is chosen where the mentioned conductors are represented together as a grounded perfectly conductive disc of radius R, positioned a short distance δ behind the screen, as depicted in FIG. 16. Since the grounded conductive disc carries polarization charges, it is called the polarization disc. FIG. 16 shows the circular CRT screen 88 and the polarization disc 101, briefly called “plates”. For small distances δ, the capacitance density between the plates of opposite polarity is nearly equal to ε/δ, where ε is the permittivity of free space. The charge distributions on the screen and polarization disc are respectively εV(r)/δ+q0 and −εV(r)/δ+q0, where the εV(r)/δ terms denote opposing charge densities at the end of the dense field lines that run between the two plates. That the part q0 is needed as well will become clear in the sequel.

 

The charge distributions εV(r)/δ+q0 and −εV(r)/δ+q0 on the two plates have a dipole moment with the density D  ( r ) = εV  ( r ) = J     ηε 4  π  ( 1 - ( r / R ) 2 ) , ( 12 )

Figure US06506148-20030114-M00002

 

directed perpendicular to the screen. Note that the plate separation δ has dropped out. This means that the precise location of the polarization charges is not critical in the present model, and further that δ may be taken as small as desired. Taking δ to zero, one thus arrives at the mathematical model of pulsed dipoles distributed over the circular CRT screen. The field due to the charge distribution q0 will be calculated later.

 

The electric field induced by the distributed dipoles (12) can be calculated easily for points on the centerline of the screen, with the result E  ( z ) = V  ( 0 ) R  { 2  ρ / R - R / ρ - 2   z  / R } , ( 13 )

Figure US06506148-20030114-M00003

 

where V(0) is the pulse voltage (11) at the screen center, ρ the distance to the rim of the screen, and z the distance to the center of the screen. Note that V(0) pulses harmonically with frequency ∫, because in (11) the sinusoidal part J of the beam current varies in this manner.

 

The electric field (13) due to the dipole distribution causes a potential distribution V(r)/2 over the screen and a potential distribution of −V(r)/2 over the polarization disc, where V(r) is nonuniform as given by (11). But since the polarization disc is a perfect conductor it cannot support voltage gradients, and therefore cannot have the potential distribution −V(r)/2. Instead, the polarization disc is at ground potential. This is where the charge distribution q0(r) comes in; it must be such as to induce a potential distribution V(r)/2 over the polarization disc. Since the distance between polarization disc and screen vanishes in the mathematical model, the potential distribution V(r)/2 is induced over the screen as well. The total potential over the monitor screen thus becomes V(r) of (11), while the total potential distribution over the polarization disc becomes uniformly zero. Both these potential distributions are as physically required. The electric charges q0 are moved into position by polarization and are partly drawn from the earth through the ground connection of the CRT.

 

In our model the charge distribution q0 is located at the same place as the dipole distribution, viz., on the plane z=0 within the circle with radius R. At points on the center line of the screen, the electric field due to the monopole distribution q0 is calculated in the following manner. As discussed, the monopoles must be such that they cause a potential φ0 that is equal to V(r)/2 over the disc with radius R centered in the plane z=0. Although the charge distribution q0(r) is uniquely defined by this condition, it cannot be calculated easily in a straightforward manner. The difficulty is circumvented by using an intermediate result derived from Excercise 2 on page 191 of Kellogg (1953), where the charge distribution over a thin disc with uniform potential is given. By using this result one readily finds the potential φ*(z) on the axis of this disc as φ *  ( z ) = 2 π  V *  β  ( R 1 ) , ( 14 )

Figure US06506148-20030114-M00004

 

where β(R1) is the angle subtended by the disc radius R1, as viewed from the point z on the disc axis, and V* is the disc potential. The result is used here in an attempt to construct the potential φ0(z) for a disc with the nonuniform potential V(r)/2, by the ansatz of writing the field as due to a linear combination of abstract discs with various radii R1 and potentials, all centered in the plane z=0. In the ansatz the potential on the symmetry axis is written φ 0  ( z ) = α     β  ( R ) + b  ∫ 0 R  β  ( R 1 )   W , ( 15 )

Figure US06506148-20030114-M00005

 

where W is chosen as the function 1−R1 2/R2, and the constants a and b are to be determined such that the potential over the plane z=0 is V(r)/2 for radii r ranging from 0 to R, with V(r) given by (11). Carrying out the integration in (15) gives

 

φ0(z)=αβ(R)−b{(1+z 2 /R 2)β(R)−|z|/R}.  (16)

 

In order to find the potential over the disc r<R in the plane z=0, the function φ0(z) is expanded in powers of z/R for 0<z<R, whereafter the powers zn are replaced by rnPn(cosθ), where the Pn are Legendre polynomials, and (r,θ) are symmetric spherical coordinates centered at the screen center. This procedure amounts to a continuation of the potential from the z-axis into the half ball r0, in such a manner that the Laplace equation is satisfied. The method is discussed by Morse and Feshbach (1953). The “Laplace continuation” allows calculation of the potential φ0 along the surface of the disc r0, the parts (13) and (19) contribute about equally to the electric field over a practical range of distances z. When going behind the monitor where z is negative the monopole field flips sign so that the two parts nearly cancel each other, and the resulting field is very small. Therefore, in the back of the CRT, errors due to imperfections in the theory are relatively large. Moreover our model, which pretends that the polarization charges are all located on the polarization disc, fails to account for the electric field flux that escapes from the outer regions of the back of the screen to the earth or whatever conductors happen to be present in the vincinity of the CRT. This flaw has relatively more serious consequences in the back than in front of the monitor.

 

Screen emissions in front of a CRT can be cut dramatically by using a grounded conductive transparent shield that is placed over the screen or applied as a coating. Along the lines of our model, the shield amounts to a polarization disc in front of the screen, so that the latter is now sandwiched between to grounded discs. The screen has the pulsed potential distribution V(r) of (11), but no electric flux can escape. The model may be modified by choosing the polarization disc in the back somewhat smaller than the screen disc, by a fraction that serves as a free parameter. The fraction may then be determined from a fit to measured fields, by minimizing the relative standard deviation between experiment and theory.

 

In each of the electron beams of a CRT, the beam current is a nonlinear function of the driving voltage, i.e., the voltage between cathode and control grid. Since this function is needed in the normalization procedure, it was measured for the 15″ computer monitor that has been used in the ½ Hz sensory resonance experiments and the electric field measurements. Although the beam current density j can be determined, it is easier to measure the luminance, by reading a light meter that is brought right up to the monitor screen. With the RGB values in the VB6 program taken as the same integer K, the luminance of a uniform image is proportional to the image intensity I. The luminance of a uniform image was measured for various values of K. The results were fitted with

 

I=c 1 K γ,  (20)

 

where c1 is a constant. The best fit, with 6.18% relative standard deviation, was obtained for γ=2.32.

 

Screen emissions also occur for liquid crystal displays (LCD). The pulsed electric fields may have considerable amplitude for LCDs that have their driving electrodes on opposite sides of the liquid crystal cell, for passive matrix as well as for active matrix design, such as thin film technology (TFT). For arrangements with in-plane switching (IPS) however, the driving electrodes are positioned in a single plane, so that the screen emission is very small. For arrangements other than IPS, the electric field is closely approximated by the frin

Manali, (alt. 1,950 m or 6,398 ft) in the Beas River valley, is an important hill station in the Himalayan mountains of Himachal Pradesh, India, near the northern end of the Kullu Valley. Manali is administratively a part of the Kullu district. The population is approx. 30,000. The small town was the beginning of an ancient trade route to Ladakh and, from there, over the Karakoram Pass on to Yarkand and Khotan in the Tarim Basin. Manali and its surrounding areas are of great significance to the Indian culture and heritage as it was the home and abode of the Saptarshi or seven sages. The ancient cave temple, Hidimba Devi Temple, is not far from town.

Contents

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* 1 Geography

* 2 Demographics

* 3 Etymology

* 4 History

* 5 Transport

* 6 Tourism in Manali

o 6.1 Tourist Attractions

o 6.2 Places around Manali

o 6.3 Adventure Sports

* 7 Notes

* 8 References

* 9 External links

 

[edit] Geography

 

Manali is located at [show location on an interactive map] 32°10′N 77°06′E / 32.16, 77.1[1]. It has an average elevation of 2625 metres (8612 feet).

 

[edit] Demographics

 

As of 2001 India census[2], Manali had a population of 6265. Males constitute 64% of the population and females 36%. Manali has an average literacy rate of 74%, higher than the national average of 59.5%: male literacy is 80%, and female literacy is 63%. In Manali, 9% of the population is under 6 years of age.

 

[edit] Etymology

 

Manali is named after the Brahmin lawgiver Manu. The word Manali literally means “the abode of Manu”. Legend has it that sage Manu stepped off his ark in Manali to recreate human life after a great flood had deluged the world. Manali is known as the "Valley of the Gods". The Old Manali village has an ancient temple dedicated to sage Manu.

 

[edit] History

 

In ancient times, the valley was sparsely populated by nomadic hunters known as "rakshas". The next arrivals were the shepherds who arrived from the Kangra valley and settled to take up agriculture. Some of the earliest inhabitants of the region are the 'naur' or 'nar', which is a caste unique to the Kullu valley. Only a few naur families are known to exist now. A naur family in the village Soyal near Haripur on the west bank of Manali was famous for the vast land they owned and their practice of having 'rakshas' as their labourers.

 

The British were responsible for introducing apples and trout which were not native to Manali. It is said that when apple trees were first planted the fruits were so plentiful that often branches, unable to bear the weight would collapse. To this day apple along with plum and pear remains the best source of income for the majority of its inhabitants.

 

Tourism in Manali received a real boost after the rise of militancy in Kashmir in the late 1980s. This once quiet village was transformed into a bustling town with hundreds of hotels and restaurants.

 

[edit] Transport

Mall street, Manali

 

Manali is well connected by road to Delhi through NH-21 which goes on the Leh and is the world's highest motorable road.[citation needed] Leading up to Manali from New Delhi are the towns of Panipat and Ambala in Haryana, Chandigarh(Union Territory), Ropar in Punjab, and Bilaspur, Sundernagar, and Mandi in Himachal.

 

Manali is not easily approachable by rail. The nearest broad gauge railheads are at Chandigarh (315 km), Pathankot (325 km) and Kalka (310 km). The nearest narrow gauge railhead is at Joginder Nagar (135 km)

 

The nearest airport is at Bhuntar, which is about 50 km from Manali. The only private airline in the region is Jagson Airlines. Offlate services have been started by Air Deccan as well as Indian Airlines who fly daily to Bhuntar Airport.

 

[edit] Tourism in Manali

Traditional home, Manali, 2004

River Beas and mountains as seen from Van Vihar

A view of Rohtang Pass in Manali

Mountain ranges in Manali

Bridge in the middle of town with prayer flags

Buddha Statue at Buddhist monastery

Image:Snowfallinmanali.JPG

A view of Circuit House Road covered in snow

  

[edit] Tourist Attractions

 

Manali is a popular Himalayan tourist destination and accounts for nearly a quarter of all tourist arrivals in Himachal Pradesh. It is visited by many trekkers who follow the hashish trail. Manali's charas is considered to be the best in India. The valleys provide natural U.V lights as fields are high up the mountain and high grade grows directly from the sunlight.ala. Manali's cool atmosphere provides a perfect haven for the ones afflicted by the hot Indian summers. It is famous for adventure sports like skiing, hiking, mountaineering, para gliding, rafting, trekking, kayaking, and mountain biking. It also offers hot springs, spectacular religious shrines and temples, Tibetan Buddhist temples, and trekking in the surrounding mountains.

 

Naggar Fort south of Manali is a reminder of the 1500 year old Pal Dynasty. Made from rocks, stones, and elaborate wood carvings, it is an ensemble of the rich and elegant artworks of Himachal. The castle was later converted to a rest house and luxury hotel. Tourists often stop at the castle to see the small shrine located in the building's courtyard, a fine example of architecture and design from the Pal Dynasty.

 

The often visited site in Manali is the Dhungri or Hadimba Temple. Erected in 1533, this temple is dedicated to the local deity Hadimba, wife of the Pandava prince, Bhim. A major festival is held here in the month of May. The temple is noted for its four-storeyed pagoda and exquisite wooden carvings.

 

Manali is known for its shiny gompas or Buddhist monasteries. With the highest concentration of Tibetan refugees in the entire Kullu valley, it is famous for its Gadhan Thekchhokling Gompa, built in 1969. The monastery is maintained by donations from the local community and through the sale of hand-woven carpets in the temple workshop

 

The smaller and more modern Himalayan Nyingamapa Gompa stands nearer the bazaar, in a garden blooming with sunflowers. Its main shrine, lit by dozens of electric bulbs and fragrant with Tibetan incense, houses a colossal gold-faced Buddha, best viewed from the small room on the first floor.

 

The Museum of Traditional Himachal Culture, near the Hadimba temple, is worth a visit, which houses artifacts of folk art of the entire Kullu valley.

 

[edit] Places around Manali

 

Rohtang Pass, at an altitude of 13,050 feet above sea level, is another adventure tourist site where it can be cold even on a summer day. It is the highest point on the Manali-Keylong road and provides a wide panoramic view of mountains rising far above clouds, which is truly breath taking. Close by is a small lake called Dassaur Lake. Beas Kund, the source of river Beas, is also nearby. In winter, the road of Rothang Pass is closed.

 

Rahala waterfalls: About 16 km from Manali at the start of the climb to the Rohtang Pass, are the beautiful Rahalla Falls at an altitude of 2,501 m.

 

Monasteries: Manali is known for its shiny gompas or Buddhist monasteries. It is maintained by donations from the local community and by sale of hand-woven carpets in the temple workshop.

 

Rani Nala - 46 km from Manali, it is the glacier point where snow is available throughout the year.

 

Vashist Hot Water Springs and Temple: Around 3 km from Manali, across the Beas river is Vashist, a small village with natural sulphur springs. Modern bathhouses,now closed, due to a conflict with the elders of the village and Manali council. Vasistha [3] a sage narrated Yoga Vasishtha an ancient scripture to Rama. A unique and an extremely profound discourse, that provides innumerable insights and secrets to the inner world of consciousness. This extremely huge scripture covers all the topics that relate to the spiritual study of a seeker. Vaishisht, also boasts a pair of old stone temples, opposite each other above the main square. Dedicated to the local patron saint Vashista, the smaller of the two opens on to a partially covered courtyard, and is adorned with elaborate woodcarvings those lining the interior of the shrine, blackened by years of oil-lamp and incense smoke, are particularly fine. In this ornate quadrangle is the resting place of the local and transient sadhus, drinking chai, and smoking chillums with whoever will join them in reverence to The Lord Shiva and Guru Vashshist. The temple baths are separated into male and female and the water is often unbearably hot.

  

Solang valley, popularly known as Snow Point, is 13 km northwest of Manali and famous for its 300-meter ski lift. It is a picturesque spot and offers splendid views of glaciers and the snow-capped mountains. Jagatsukh, the former capital of Manali, is also an important spot.

 

At a distance of 3 km northwest of Manali is Old Manali, famous for its orchards and old guesthouses. There is ruined fort here by the name of Manaligarh. There is also the Manu Maharishi Temple, dedicated to sage Manu.

 

Manikaran: 85 km from Manali and 45 km from Kullu, lies in the Parvati Valley. Here icy cold waters of the Parvati river co-exist with hot-water springs side-by-side. The springs are known for their healing properties.

 

[edit] Adventure Sports

 

Skiing is a major pastime in Manali. Facilities for skiing are available at Solang Nullah (January-March) and Rohtang La (during summer). The Mountaineering Institute at Solang Nullah is a good training institute. Heli skiing is possible at the deep snowfields.

Skiing at Solang

 

The Mountaineering Institute and Allied Sports is about 3 km from the Mall and offers mountaineering and kayaking courses. Kayaking is possible on the Beas River.

 

There are several good hikes from Manali. The 12 km hike up the western banks of the Beas to the Solang Valley is noteworthy. Lama Dugh meadow is a 6 km hike up to the Manalsu Nala, west of Manali town.

 

For the best trekking expedition, take a trek from Solang Valley, on to Dhundhi and from there to Dussar lake and then onwards to Manali. This stretch will take you to places you would have only dreamt of. Pure, unadulterated adventure and fun. Be sure to have a good guide at your disposal who knows this area otherwise you would be lost forever. The trek would typically last for 5 days.

 

In the summers, several travel agencies organize paragliding on the slopes of the Solang Nullah. The charges generally include accommodation, food, equipment, and a guide, but not transport.

 

From May to July and, depending on the monsoons, from mid-September to mid-October, some basic rafting is possible on the Beas. The trips generally begin at Pirdi and continue 16 km down to Jhiri.

 

The HPTDC provides day permits for fishing. Permits can be obtained also at Patlikhul. Angling in the Kullu valley is possible at Larji, Katrain and Kasol.

 

Beas Kund is the lake from which the River Beas originates. It is considered holy and sacred. Besides being a holy pilgrimage place, it is a popular destination for trekking.

River Crossing over Beas is a popular sport in Manali

 

Manali is among the most popular adventure sports destinations in India. Manali offers opportunities for mountaineering, skiing, trekking, paragliding, white water rafting, river crossing and mountain biking. Yak skiing is a sport unique to this area.[4]. Manali also featured in Time magazine's "Best of Asia" for its "Extreme Yak Sports".[4]

External view of Lister House

 

Image Disclaimer - Please note that all of the images shown are for illustrative purposes only. The rooms pictured are not necessarily typical of the accommodation available at Lister House, which can vary in terms of size, configuration, and finish.

Detail of the bottom of the ariel showing how it was cut and bent to make an effective hook for Ernest's hopper windows.

Note also the way the USB extension cable is secured using cable ties.

Helsinki Cathedral (Helsingin tuomiokirkko) is the Finnish Evangelical Lutheran cathedral of the Diocese of Helsinki, located in the neighbourhood of Kruununhaka in the centre of Helsinki, Finland. The church was originally built from 1830-1852 as a tribute to the Grand Duke of Finland, Tsar Nicholas I of Russia. It was also known as St Nicholas' Church until the independence of Finland in 1917. It is a major landmark of the city. en.wikipedia.org/wiki/Helsinki_Cathedral

 

Helsinki is the capital and most populous city of Finland. Located on the shore of the Gulf of Finland, it is the seat of the region of Uusimaa in southern Finland, and has a population of 650,058. The city's urban area has a population of 1,268,296, making it by far the most populous urban area in Finland as well as the country's most important center for politics, education, finance, culture, and research. Helsinki is located 80 kilometres north of Tallinn, Estonia, 400 km east of Stockholm, Sweden, and 300 km west of Saint Petersburg, Russia. It has close historical ties with these three cities. Together with the cities of Espoo, Vantaa, and Kauniainen, and surrounding commuter towns, Helsinki forms the Greater Helsinki metropolitan area, which has a population of nearly 1.5 million. Often considered to be Finland's only metropolis, it is the world's northernmost metro area with over one million people as well as the northernmost capital of an EU member state. After Stockholm and Oslo, Helsinki is the third largest municipality in the Nordic countries. The city is served by the international Helsinki Airport, located in the neighboring city of Vantaa, with frequent service to manO destinations in Europe and Asia. Helsinki was the World Design Capital for 2012, the venue for the 1952 Summer Olympics, and the host of the 52nd Eurovision Song Contest in 2007. Helsinki has one of the highest urban standards of living in the world. In 2011, the British magazine Monocle ranked Helsinki the world's most liveable city in its liveable cities index. In the Economist Intelligence Unit's 2016 liveability survey, Helsinki was ranked ninth among 140 cities. en.wikipedia.org/wiki/Helsinki

Spent the day enjoying the wind, sailing out on the Broads and stopped to take a few photos on the drive home.

 

Just down the road from me is this new Wind Turbine. I had only seen it in the distance but the field it was in was not fenced off so got a few shots. I took a few. Shot with a dark exposure, but used an external flash unit to 'fill in' the foreground. It came out quite cool with the wind thrashing against the grass.

External view of Kelvinhaugh Gate.

 

Image Disclaimer - Please note that all of the images shown are for illustrative purposes only. The rooms pictured are not necessarily typical of the accommodation available at Kelvinhaugh Gate, which can vary in terms of size, configuration, and finish.

Ethiopia

External view of Murano Street accommodation block

Photos for participants and USLA. Tag waterbloggged! Others: DON'T PUT ON EXTERNAL SITES WITHOUT PERMISSION.

A project for renovation of a property in Cuffley. Visit : www.allweathercoating.co.uk/case-studies/cuffley-2/

The SPAR Great Ireland Run 2013 was held in the Phoenix Park, Dublin, Ireland on Sunday 14th April 2013 at 13:10 and 13:30 respectively. The Great Ireland Run is now probably the largest 10KM running event in Ireland. The race also incorporates the AAI National 10km Championships. This category is for club athletes in Ireland only. However, there is also the main field race where anyone, regardless of being with an athletic club or not, can enter and race. The elite women and club women's race started at 13:10 whilst the male club and main field event started at 13:30. The race starts on Chesterfield Avenue and takes a clockwise route - first over to the Blackhorse Avenue sid of the park, crossing Chesterfield avenue again. The race then descends down the Kyber pass before the runners must take the challenge of the famous S-Bends on the Chapelizod side including a steep climb at 7KM. Finally the race winds its way around the Furry Glen, before finishing very close to the starting point of the race.

 

These photographs are taken at the 7 KM marker on Chapelizod Hill. They are from the time period 13:35 (leading elite women) until all waves have passed this point (approximately 14:42). There are no start or finish line photographs.

 

Elite Womens and Irish Womens National Championship field: Flickr set is here [http://www.flickr.com/photos/peterm7/sets/72157633232150933/]

Elite Men, Irish National Championship, and the main field: Flickr set is here [http://www.flickr.com/photos/peterm7/sets/72157633240224417/]

 

I really enjoyed taking these photographs. It is the first time in a long time where I have been able to photograph a race I was not participating in. It was a really great experience. Despite the tough course and the horrible head winds I got so many nods and "hellos" from hundreds of runners I knew there and from thousands of others I have yet to get to know ;-) It is a really great event.

 

PLEASE NOTE! These are completely unofficial SPAR Great Ireland Run 2013 photographs. We are not affiliated in any way to the organisation of the Great Ireland Run. These photographs are not for commercial use nor are they provided here on Flickr for commercial usage. If you require commercially available photographs please use the weblinks provided below here to find more information.

 

Overall Race Summary

Participants: Approximately 10,000 people

Weather: Dry, cold, with very strong head wind

Course: Completely traffic free course - all on excellent tarmac roads. The course is undulating from 4KM to about 9KM giving a real test of 10KM strength.

Refreshments: No refreshments - goody bags provided to all participants.

 

Some links, related to this race, which you might find useful:

 

Great Ireland Run Homepage: www.greatirelandrun.org/Default.aspx

Boards.ie Athletics Discussion Thread on this race: www.boards.ie/vbulletin/showthread.php?t=2056907184

Great Ireland Run Facebook Page: www.facebook.com/greatirelandrun

 

Please note: that we cannot be responsible for the content of any external links (outside of ourown Flickr account) as we have no control over them. Links are provided for your information only. Responsibility lies solely with the operators of those websites.

 

How can I get a full resolution copy of these photographs?

 

All of the photographs here on this Flickr set have a visible watermark embedded in them. All of the photographs posted here on this Flickr set are available, free, at no cost, at full resolution WITHOUT watermark. We take these photographs as a hobby and as a contribution to the running community in Ireland. We do not know of any other photographers who operate such a policy. Our only "cost" is our request that if you are using these images: (1) on social media sites such as Facebook, Tumblr, Pinterest, Twitter,LinkedIn, Google+, Google Orkut etc or (2) other websites, web multimedia, commercial/promotional material that you provide a link back to our Flickr page to attribute us. This also means the use of these images for Facebook profile pictures. In these cases please make a wall post with a link to our Flickr page. If you do not know how this should be done for Facebook or other media please email us and we will be happy to help suggest how to link to us.

 

Please email petermooney78 AT gmail DOT com with the links to the photographs you would like to obtain a full resolution copy of. We also ask race organisers, media, etc to ask for permission before use of our images for flyers, posters, etc. We reserve the right to refuse a request.

 

In summary please remember - all we ask is for you to link back to our Flickr set or Flickr pages. We are not posting photographs to Flickr for commercial reasons. If you really like what we do please spread the link around, send us an email, leave a comment beside the photographs, send us a Flickr email, etc.

 

I ran the race - but my photograph doesn't appear here in your Flickr set!

 

As mentioned above we take these photographs as a hobby and as a voluntary contribution to the running community in Ireland. Very often we have actually ran in the same race and then switched to photographer mode after we finished the race. Consequently, we have no obligations to capture a photograph of every participant in the race. However, we do try our very best to capture as many participants as possible. But this is sometimes not possible for a variety of reasons:

 

    You were hidden behind another participant as you passed our camera

    Weather or lighting conditions meant that we had some photographs with blurry content which we did not upload to our Flickr set

    There were too many people - some races attract thousands of participants and as amateur photographs we cannot hope to capture photographs of everyone

    We simply missed you - sorry about that - we did our best!

  

You can email us petermooney78 AT gmail DOT com to enquire if we have a photograph of you which didn't make the final Flickr selection for the race. But we cannot promise that there will be photograph there. As alternatives we advise you to contact the race organisers to enquire if there were (1) other photographs taking photographs at the race event or if (2) there were professional commercial sports photographers taking photographs which might have some photographs of you available for purchase. You might find some links for further information above.

 

If you want to contribute something for these images?

We do not charge for these images. We take these photographs as our contribution to the running community in Ireland. If you feel that the image(s) you request are good enough that you would ordinarily pay for their purchase we would suggest that you can provide a donation to any of the great charities in Ireland who do work for Cancer Care or Cancer Research in Ireland.

 

Don't like your photograph here?

That's OK! We understand!

 

If, for any reason, you are not happy or comfortable with your picture appearing here in this photoset on Flickr then please email us at petermooney78 AT gmail DOT com and we will remove it as soon as possible.

 

This is the addon plumbing for a constructors' hut in Denmark.

Extended tripod held above my head. Pretty standard RAW conversion in Lightroom.

.

 

Alexei Arkhipovich Leonov[a] (30 May 1934 – 11 October 2019) was a Soviet Russian cosmonaut, Air Force major general, writer, and artist. On 18 March 1965, he became the first human to conduct a spacewalk, exiting the capsule during the Voskhod 2 mission for 12 minutes and 9 seconds.

 

In July 1975, Leonov commanded the Soyuz capsule in the Soyuz–Apollo mission, which docked in space for two days with an American Apollo capsule.

Contents

 

1 Early life and military service

2 Soviet space programme

3 Later life and death

4 Legacy

4.1 Russian awards and honours

4.2 Foreign awards

4.3 Public organisations

4.4 Other awards and titles

5 See also

6 Notes

7 References

8 Sources

9 Further reading

10 External links

 

Early life and military service

 

Leonov was born on 30 May 1934 in Listvyanka, West Siberian Krai, Russian SFSR.[3] His grandfather was forced to relocate to Siberia for his role in the 1905 Russian Revolution. He was the eighth of nine surviving children born to Yevdokia née Sotnikova and Arkhip.[b][4]

 

In 1936, his father was arrested and declared an "enemy of the people". Leonov wrote in his autobiography: "He was not alone: many were being arrested. It was part of a conscientious drive by the authorities to eradicate anyone who showed too much independence or strength of character. These were the years of Stalin's purges. Many disappeared into remote gulags and were never seen again."[5] The family moved in with one of his married sisters in Kemerovo. His father rejoined the family in Kemerovo after he was released. He was compensated for his wrongful imprisonment.[4] Leonov used art as a way to provide more food for the family. He began his art career by drawing flowers on ovens and later painted landscapes on canvasses.[4]

 

The Soviet government encouraged its citizens to move to Soviet-occupied Prussia, so in 1948 his family relocated to Kaliningrad.[6] Leonov graduated from secondary school (No. 21) in 1953.[6] He applied to the Academy of Arts in Riga, Latvia, but decided not to attend due to the high tuition costs. Leonov decided to join a Ukrainian preparatory flying school in Kremenchug; he made his first solo flight in May 1955. While at same time indulging in his passion for art by studying part-time in Riga, Leonov started an advanced two-year course to become a fighter pilot at the Chuguev Higher Air Force Pilots School in the Ukrainian SSR.[6]

 

On 30 October 1957, Leonov graduated with an honour's degree and was commissioned a lieutenant in the 113th Parachute Aviation Regiment, part of the 10th Engineering Aviation Division of the 69th Air Army in Kiev.[6] On 13 December 1959, he married Svetlana Pavlovna a day before he moved to East Germany to his new assignment with the 294th Reconnaissance Regiment of the 24th Air Army.[6]

Soviet space programme

Alexei Leonov (left, back row) with fellow cosmonauts in 1965

March 1965, the first space walk

 

He was one of the 20 Soviet Air Force pilots selected to be part of the first cosmonaut training group in 1960.[7] Leonov was a member of the Communist Party of the Soviet Union (the only cosmonaut who was not was Konstantin Feoktistov). His walk in space was originally to have taken place on the Voskhod 1 mission, but this was cancelled, and the historic event happened on the Voskhod 2 flight instead.[8] He was outside the spacecraft for 12 minutes and nine seconds on 18 March 1965, connected to the craft by a 4.8-metre (16 ft) tether.[7] At the end of the spacewalk, Leonov's spacesuit had inflated in the vacuum of space to the point where he could not re-enter the airlock.[7] He opened a valve to allow some of the suit's pressure to bleed off and was barely able to get back inside the capsule.[7][9] Leonov had spent eighteen months undergoing weightlessness training for the mission.[10]

 

In 1968, Leonov was selected to be commander of a circumlunar Soyuz 7K-L1 flight. This was cancelled because of delays in achieving a reliable circumlunar flight (only the later Zond 7 and Zond 8 members of the programme were successful) and the Apollo 8 mission had already achieved that step in the Space Race. He was also selected to be the first Soviet person to land on the Moon, aboard the LOK/N1 spacecraft.[8] This project was also cancelled. (The design required a spacewalk between lunar vehicles, something that contributed to his selection.) Leonov was to have been commander of the 1971 Soyuz 11 mission to Salyut 1, the first crewed space station, but his crew was replaced with the backup after one of the members, cosmonaut Valery Kubasov, was suspected to have contracted tuberculosis (the other member was Pyotr Kolodin).[11]

 

Leonov was to have commanded the next mission to Salyut 1, but this was scrapped after the deaths of the Soyuz 11 crew members, and the space station was lost.[12] The next two Salyuts (actually the military Almaz station) were lost at launch or failed soon after, and Leonov's crew stood by. By the time Salyut 4 reached orbit, Leonov had been switched to a more prestigious project.[13][14]

the five crew members of ASTP sitting around a miniature model of their spacecraft

Apollo-Soyuz crew in 1975

 

Leonov's second trip into space was as commander of Soyuz 19, the Soviet half of the 1975 Apollo-Soyuz mission – the first joint space mission between the Soviet Union and the United States.[13][15]

 

From 1976 to 1982, Leonov was the commander of the cosmonaut team ("Chief Cosmonaut") and deputy director of the Yuri Gagarin Cosmonaut Training Center, where he oversaw crew training. He also edited the cosmonaut newsletter Neptune. He retired in 1992.[8]

Later life and death

Leonov's 1967 painting Near the Moon and a screenshot from 2001: A Space Odyssey (1968)

 

Leonov was an accomplished artist whose published books include albums of his artistic works and works he did in collaboration with his friend Andrei Sokolov. Leonov took coloured pencils and paper into space, where he sketched the Earth and drew portraits of the Apollo astronauts who flew with him during the 1975 Apollo–Soyuz Test Project.[16][17] Arthur C. Clarke wrote in his notes to 2010: Odyssey Two that, after a 1968 screening of 2001: A Space Odyssey, Leonov pointed out to him that the alignment of the Moon, Earth, and Sun shown in the opening is essentially the same as that in Leonov's 1967 painting Near the Moon, although the painting's diagonal framing of the scene was not replicated in the film. Clarke kept an autographed sketch of this painting—which Leonov made after the screening—hanging on his office wall.[18] Clarke dedicated 2010: Odyssey Two to Leonov and Soviet physicist Andrei Sakharov;[19] and the fictional spaceship in the book is named Cosmonaut Alexei Leonov.[20]

 

Together with Valentin Selivanov, Leonov wrote the script for the 1980 science fiction film The Orion Loop.[21]

 

In 2001, he was a vice president of Moscow-based Alfa-Bank and an adviser to the first deputy of the Board.[22]

 

In 2004, Leonov and former American astronaut David Scott began work on a dual memoir covering the history of the Space Race between the United States and the Soviet Union. Titled Two Sides of the Moon: Our Story of the Cold War Space Race, it was published in 2006. Neil Armstrong and Tom Hanks both wrote introductions to the book.[23]

 

Leonov was interviewed by Francis French for the book Into That Silent Sea by Colin Burgess and French.[24]

 

Leonov died on 11 October 2019 after a long illness in Moscow. His funeral took place on 15 October.[25] He was 85[26] and the last living member of the five cosmonauts in the Voskhod programme.[27]

Legacy

Alexei Leonov (right) shares a moment with Anton Shkaplerov (left) in October 2011.

 

The Leonov crater, near Mare Moscoviense (Sea of Moscow) on the far side of the Moon, was named after Leonov in 1970.[28][29]

9533 Aleksejleonov, an asteroid first observed in 1981, was named for him.[30]

Leonov, along with Rusty Schweickart, established the Association of Space Explorers in 1985. Membership is open to all people who have orbited the Earth.[31]

The film The Age of Pioneers (2017) is based on Leonov's account of the Voskhod 2 mission. Leonov was portrayed by Yevgeny Mironov.[32] He was a technical adviser for the movie; the director cut all scenes featuring Gagarin–about 40 minutes of film–so Leonov could be the focus.[33]

The song "E.V.A" by Public Service Broadcasting on their 2015 album, The Race for Space, references Leonov becoming the first man to undertake extravehicular activity in space.[34]

 

Russian awards and honours

Leonov in 2016, wearing his two Hero of the Soviet Union medals

Alexei Leonov on 1965 USSR 10 kopek stamp.

 

Twice Hero of the Soviet Union (23 March 1965[35] and 22 July 1975[36])

Two Orders of Lenin (23 March 1965[37] and 22 July 1975[36])

Pilot-Cosmonaut of the USSR (1965)[37]

Merited Master of Sport of the USSR (1965)[38]

Order of the Red Star (1961)[38]

Order for Service to the Homeland in the Armed Forces of the USSR, 3rd class (1975)[38]

Jubilee Medal "Twenty Years of Victory in the Great Patriotic War 1941–1945"

Jubilee Medal "40 Years of the Armed Forces of the USSR"

Jubilee Medal "50 Years of the Armed Forces of the USSR"

Jubilee Medal "60 Years of the Armed Forces of the USSR"

Jubilee Medal "70 Years of the Armed Forces of the USSR"

Medal "Veteran of the Armed Forces of the USSR"

Medals "For Impeccable Service", 1st, 2nd and 3rd classes

Lenin Komsomol Prize (1980)[39]

USSR State Prize (1981)[39]

Order for Merit to the Fatherland, 4th class (2 March 2000)[40]

Order of Friendship (12 April 2011)[41]

Order "For Merit to the Fatherland", 3rd class (22 May 2014)[42]

Order "For Merit to the Fatherland", 1st class (29 May 2019)[43]

 

Foreign awards

 

Hero of Socialist Labour (People's Republic of Bulgaria, 1965)[38]

Order of Georgi Dimitrov (People's Republic of Bulgaria, 1965)[38]

Artur Becker Medal [de; ru] (German Democratic Republic, 1965)[38]

Order of Karl Marx (German Democratic Republic, 1965)[38]

Order of the Flag of the Republic of Hungary (1965)[38]

Hero of Labor (Democratic Republic of Vietnam, 1966)[38]

Order of Civil Merit, 1st class (Syria, 1966)[38]

Order of Merit, 3rd class (Ukraine, 2011)[44]

 

Public organisations

Leonov, Stephen Hawking, and Brian May at the Starmus Festival, 2016

 

1975 Gold Space Medal from the Fédération Aéronautique Internationale (FAI) in 1976. FAI created an exception which allowed Thomas P. Stafford to be awarded it alongside him; typically the award is restricted to one person per year.[45][46]

International Space Hall of Fame (1976)[47]

International Air & Space Hall of Fame, inducted in 2001, along with Valeri Kubasov, Vance D. Brand, Deke Slayton, and Thomas P. Stafford[48]

Ludwig Nobel Prize (2007)[49][50]

Elmer A. Sperry Award (US, 2008), with Konstantin Bushuyev, Thomas P. Stafford, and Glynn Lunney[51]

Order of Saint Constantine the Great (Union of the Golden Knights of the Order of St. Constantine the Great)[38]

Order "Golden Star" (Foundation Heroes of the Soviet Union and Heroes of the Russian Federation)[38]

Order the "Pride of Russia" (Foundation for the "Pride of the Fatherland", 2007)[38]

National Award "To the Glory of the Fatherland" in the "Glory to Russia" class (International Academy of Social Sciences and International Academy of patronage, 2008)[38]

Order of "the Glory of the Fatherland", 2nd class (2008)[38]

 

Other awards and titles

 

Commander of the Order of Saint Anna III degree (2008), by Grand Duchess Maria Vladimirovna of Russia[52]

Commander of the Order of Saint Anna II degree (2011), by Grand Duchess Maria Vladimirovna of Russia[52]

Honorary member of the Russian Academy of Arts[53]

External Affairs Minister Dr. S. Jaishankar met Diplomatic Advisor to the President of UAE, H.E. Dr. Anwar Mohammed Gargesh in Abu Dhabi

External

External Affairs Minister Dr. S. Jaishankar paid tributes to 26/11 terror attack victims

equinis correction, ring fixation

Manali, (alt. 1,950 m or 6,398 ft) in the Beas River valley, is an important hill station in the Himalayan mountains of Himachal Pradesh, India, near the northern end of the Kullu Valley. Manali is administratively a part of the Kullu district. The population is approx. 30,000. The small town was the beginning of an ancient trade route to Ladakh and, from there, over the Karakoram Pass on to Yarkand and Khotan in the Tarim Basin. Manali and its surrounding areas are of great significance to the Indian culture and heritage as it was the home and abode of the Saptarshi or seven sages. The ancient cave temple, Hidimba Devi Temple, is not far from town.

Contents

[hide]

 

* 1 Geography

* 2 Demographics

* 3 Etymology

* 4 History

* 5 Transport

* 6 Tourism in Manali

o 6.1 Tourist Attractions

o 6.2 Places around Manali

o 6.3 Adventure Sports

* 7 Notes

* 8 References

* 9 External links

 

[edit] Geography

 

Manali is located at [show location on an interactive map] 32°10′N 77°06′E / 32.16, 77.1[1]. It has an average elevation of 2625 metres (8612 feet).

 

[edit] Demographics

 

As of 2001 India census[2], Manali had a population of 6265. Males constitute 64% of the population and females 36%. Manali has an average literacy rate of 74%, higher than the national average of 59.5%: male literacy is 80%, and female literacy is 63%. In Manali, 9% of the population is under 6 years of age.

 

[edit] Etymology

 

Manali is named after the Brahmin lawgiver Manu. The word Manali literally means “the abode of Manu”. Legend has it that sage Manu stepped off his ark in Manali to recreate human life after a great flood had deluged the world. Manali is known as the "Valley of the Gods". The Old Manali village has an ancient temple dedicated to sage Manu.

 

[edit] History

 

In ancient times, the valley was sparsely populated by nomadic hunters known as "rakshas". The next arrivals were the shepherds who arrived from the Kangra valley and settled to take up agriculture. Some of the earliest inhabitants of the region are the 'naur' or 'nar', which is a caste unique to the Kullu valley. Only a few naur families are known to exist now. A naur family in the village Soyal near Haripur on the west bank of Manali was famous for the vast land they owned and their practice of having 'rakshas' as their labourers.

 

The British were responsible for introducing apples and trout which were not native to Manali. It is said that when apple trees were first planted the fruits were so plentiful that often branches, unable to bear the weight would collapse. To this day apple along with plum and pear remains the best source of income for the majority of its inhabitants.

 

Tourism in Manali received a real boost after the rise of militancy in Kashmir in the late 1980s. This once quiet village was transformed into a bustling town with hundreds of hotels and restaurants.

 

[edit] Transport

Mall street, Manali

 

Manali is well connected by road to Delhi through NH-21 which goes on the Leh and is the world's highest motorable road.[citation needed] Leading up to Manali from New Delhi are the towns of Panipat and Ambala in Haryana, Chandigarh(Union Territory), Ropar in Punjab, and Bilaspur, Sundernagar, and Mandi in Himachal.

 

Manali is not easily approachable by rail. The nearest broad gauge railheads are at Chandigarh (315 km), Pathankot (325 km) and Kalka (310 km). The nearest narrow gauge railhead is at Joginder Nagar (135 km)

 

The nearest airport is at Bhuntar, which is about 50 km from Manali. The only private airline in the region is Jagson Airlines. Offlate services have been started by Air Deccan as well as Indian Airlines who fly daily to Bhuntar Airport.

 

[edit] Tourism in Manali

Traditional home, Manali, 2004

River Beas and mountains as seen from Van Vihar

A view of Rohtang Pass in Manali

Mountain ranges in Manali

Bridge in the middle of town with prayer flags

Buddha Statue at Buddhist monastery

Image:Snowfallinmanali.JPG

A view of Circuit House Road covered in snow

  

[edit] Tourist Attractions

 

Manali is a popular Himalayan tourist destination and accounts for nearly a quarter of all tourist arrivals in Himachal Pradesh. It is visited by many trekkers who follow the hashish trail. Manali's charas is considered to be the best in India. The valleys provide natural U.V lights as fields are high up the mountain and high grade grows directly from the sunlight.ala. Manali's cool atmosphere provides a perfect haven for the ones afflicted by the hot Indian summers. It is famous for adventure sports like skiing, hiking, mountaineering, para gliding, rafting, trekking, kayaking, and mountain biking. It also offers hot springs, spectacular religious shrines and temples, Tibetan Buddhist temples, and trekking in the surrounding mountains.

 

Naggar Fort south of Manali is a reminder of the 1500 year old Pal Dynasty. Made from rocks, stones, and elaborate wood carvings, it is an ensemble of the rich and elegant artworks of Himachal. The castle was later converted to a rest house and luxury hotel. Tourists often stop at the castle to see the small shrine located in the building's courtyard, a fine example of architecture and design from the Pal Dynasty.

 

The often visited site in Manali is the Dhungri or Hadimba Temple. Erected in 1533, this temple is dedicated to the local deity Hadimba, wife of the Pandava prince, Bhim. A major festival is held here in the month of May. The temple is noted for its four-storeyed pagoda and exquisite wooden carvings.

 

Manali is known for its shiny gompas or Buddhist monasteries. With the highest concentration of Tibetan refugees in the entire Kullu valley, it is famous for its Gadhan Thekchhokling Gompa, built in 1969. The monastery is maintained by donations from the local community and through the sale of hand-woven carpets in the temple workshop

 

The smaller and more modern Himalayan Nyingamapa Gompa stands nearer the bazaar, in a garden blooming with sunflowers. Its main shrine, lit by dozens of electric bulbs and fragrant with Tibetan incense, houses a colossal gold-faced Buddha, best viewed from the small room on the first floor.

 

The Museum of Traditional Himachal Culture, near the Hadimba temple, is worth a visit, which houses artifacts of folk art of the entire Kullu valley.

 

[edit] Places around Manali

 

Rohtang Pass, at an altitude of 13,050 feet above sea level, is another adventure tourist site where it can be cold even on a summer day. It is the highest point on the Manali-Keylong road and provides a wide panoramic view of mountains rising far above clouds, which is truly breath taking. Close by is a small lake called Dassaur Lake. Beas Kund, the source of river Beas, is also nearby. In winter, the road of Rothang Pass is closed.

 

Rahala waterfalls: About 16 km from Manali at the start of the climb to the Rohtang Pass, are the beautiful Rahalla Falls at an altitude of 2,501 m.

 

Monasteries: Manali is known for its shiny gompas or Buddhist monasteries. It is maintained by donations from the local community and by sale of hand-woven carpets in the temple workshop.

 

Rani Nala - 46 km from Manali, it is the glacier point where snow is available throughout the year.

 

Vashist Hot Water Springs and Temple: Around 3 km from Manali, across the Beas river is Vashist, a small village with natural sulphur springs. Modern bathhouses,now closed, due to a conflict with the elders of the village and Manali council. Vasistha [3] a sage narrated Yoga Vasishtha an ancient scripture to Rama. A unique and an extremely profound discourse, that provides innumerable insights and secrets to the inner world of consciousness. This extremely huge scripture covers all the topics that relate to the spiritual study of a seeker. Vaishisht, also boasts a pair of old stone temples, opposite each other above the main square. Dedicated to the local patron saint Vashista, the smaller of the two opens on to a partially covered courtyard, and is adorned with elaborate woodcarvings those lining the interior of the shrine, blackened by years of oil-lamp and incense smoke, are particularly fine. In this ornate quadrangle is the resting place of the local and transient sadhus, drinking chai, and smoking chillums with whoever will join them in reverence to The Lord Shiva and Guru Vashshist. The temple baths are separated into male and female and the water is often unbearably hot.

  

Solang valley, popularly known as Snow Point, is 13 km northwest of Manali and famous for its 300-meter ski lift. It is a picturesque spot and offers splendid views of glaciers and the snow-capped mountains. Jagatsukh, the former capital of Manali, is also an important spot.

 

At a distance of 3 km northwest of Manali is Old Manali, famous for its orchards and old guesthouses. There is ruined fort here by the name of Manaligarh. There is also the Manu Maharishi Temple, dedicated to sage Manu.

 

Manikaran: 85 km from Manali and 45 km from Kullu, lies in the Parvati Valley. Here icy cold waters of the Parvati river co-exist with hot-water springs side-by-side. The springs are known for their healing properties.

 

[edit] Adventure Sports

 

Skiing is a major pastime in Manali. Facilities for skiing are available at Solang Nullah (January-March) and Rohtang La (during summer). The Mountaineering Institute at Solang Nullah is a good training institute. Heli skiing is possible at the deep snowfields.

Skiing at Solang

 

The Mountaineering Institute and Allied Sports is about 3 km from the Mall and offers mountaineering and kayaking courses. Kayaking is possible on the Beas River.

 

There are several good hikes from Manali. The 12 km hike up the western banks of the Beas to the Solang Valley is noteworthy. Lama Dugh meadow is a 6 km hike up to the Manalsu Nala, west of Manali town.

 

For the best trekking expedition, take a trek from Solang Valley, on to Dhundhi and from there to Dussar lake and then onwards to Manali. This stretch will take you to places you would have only dreamt of. Pure, unadulterated adventure and fun. Be sure to have a good guide at your disposal who knows this area otherwise you would be lost forever. The trek would typically last for 5 days.

 

In the summers, several travel agencies organize paragliding on the slopes of the Solang Nullah. The charges generally include accommodation, food, equipment, and a guide, but not transport.

 

From May to July and, depending on the monsoons, from mid-September to mid-October, some basic rafting is possible on the Beas. The trips generally begin at Pirdi and continue 16 km down to Jhiri.

 

The HPTDC provides day permits for fishing. Permits can be obtained also at Patlikhul. Angling in the Kullu valley is possible at Larji, Katrain and Kasol.

 

Beas Kund is the lake from which the River Beas originates. It is considered holy and sacred. Besides being a holy pilgrimage place, it is a popular destination for trekking.

River Crossing over Beas is a popular sport in Manali

 

Manali is among the most popular adventure sports destinations in India. Manali offers opportunities for mountaineering, skiing, trekking, paragliding, white water rafting, river crossing and mountain biking. Yak skiing is a sport unique to this area.[4]. Manali also featured in Time magazine's "Best of Asia" for its "Extreme Yak Sports".[4]

I bought this red corset on line. Its not v-high quality but it has allowed me to have some fun. Its a lovely red pattern and I thought I would try it externally. In this mode I think it really only goes with leggings or trousers. I went for a white blouse to give it a chance to shine

Windows & Tester Notes

  

•A window tells me I don't have permission to save notepad to desktop but it saves anyway.

•I like pin to taskbar.

•When I unplug and go outside my home network disappears. I was able to connect to the net. The network stayed when I came back in and unplugged.

•I don't notice a mail. Windows mail or outlook express.

•I'll install 2003 soon.

•I'm glad I can drag files to a folder and they Move like xp used to. I want a move feature.

•Could not load easy media transfer on xp pro machine

•Adobe flash player 9 debugger comes up in mozilla even though I have installed flash PLAYER 10

•I had problems installing an ati 650 made for windows 7 beta software. Uninstall was just as bad.

•I like the video preview box!

•I can't get the ati TV 650 wonder to load from the software disc or from the ati site using a windows 7 friendly download.

•It looks like you didn’t get the message about playing gifs.

•1/28/2009 5:11:15 AM

•Moving @ 50 gb from networked xp pro external hd to windows 7 LT

•69 processes, cpu usage %68, physical memory %51 5 apps open including mozilla with 3 tabs open to my webpage plus two fox web pages which are heavy with video and pics. Firefox at 224,00kpss

•Memory is at 1.93 gb

•1/29/2009 4:43:51 AM I have tried three or four times to open the control panel and get a runtime error. I want to uninstall a program. The control panel view opened but was blank. I had to use the drop down to select.

•Odd behavior tonight. I loaded some movie files from my Sony. Adobe premiere pro didn’t see them so I loaded adobe elements 2.0. It didn’t see them. I tried to rename the ext to .mpg they wouldn’t rename. I tried to use a bulk rename utility but it didn’t see the files… Twighlite zone. I see the files and the media player plays them. I want to cut them but do not understand.

•I started having problems with the forward button on the photo nedia viwer roday.

•1/30/2009 4:10:50 PM

•I like the thumbnail images on the desktop

•2/3/2009 6:57:56 PM

•OK it has to be a windows 7 thing with mo 2003 because I received both of these at the same time watching THE DESKTOP AND THE LAPTOP (LAPTOP HAS WINDOWS 7) . THE DESKTOP, xp pro, WAS FINE. THE LAPTOP RECEIVED GARBAGE. But I am wondering why Bella can send me the same thing and it was OK on Laptop when yours wasn't. So it is not you.

•2/4/2009 6:47:30 AM

•Pop up says ie8 not supported.

•I still haven’t found how to sort by name the icons in the quick launch area.

•I need base system deveice drivers’

•When moving files on a network from xp pro to windows 7 the move starts but often ends in can’t move thumbnail error.

•I like the way 7 easily synched with my moto q however I have trouble turning motoq into a modem.

•I have difficulty opening multiple folders at the same time

•IE comes up but then just disappears, firefox works.

•I can't get to advanced edit in mo 2003 windows 7. erroror h.

•windows 7 bogged dowen deleting duplicate files with dupe locator.

•2/8/2009 1:58:16 AM

•trying to update a techsmith camtasia I get switch to box. Finding the browser didin't help.

•When I try to use camtasia to record a power point presentation I can’t check the record from what speaker hears box.

•Ie won’t stay op[en. It opens then closes.

•Ie7 would not install. Windows said not nsupported

•Won’t work with google chrome.

•Shaneksmith1957@gmail.com

•2/9/2009 7:00:59 AM

•Sound recorder threw up multiple windows telling me it didn’t have enough temp memory to record. I have @ 200gb free on drive.

•2/17/2009 1:11:46 PM

•An infrared driver update came my way via windows beata notification. However the page disappeared and I can’t get it back. It lead me to a blank web page. I managed to save a pdf of the page with hot links but the links go nowhere. There was no explanatioin as to what the driver fixes.

•Shaneksmith1957@gmail.com

•I managed to downlload the cir driver from the hotlink.

•I am looking for 3 base system drivers

•Xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx

•2/28/2009 1:25:37 AM

•I like the desktop random change selection

•3/8/2009 3:48:36 AM

•7 has a problem with video programs. i tried importing an avi video from a networked pc using camtasia and she crapped out on me...AGAIN!!

•shaneksmith1957@gmail.com

•3/16/2009 9:09:52 AM

•windows 7 won't let total recorder record sounds heard from speaker only. This is useful when trying to record screen shots with internal sound from a website.

•shaneksmith1957@gmail.com

•Xxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxxx

•3/17/2009 9:17:25 AM

It’s a sugar coated version of XP that conflicts with my video editing programs. Microsoft has made it harder to move files with no “move” feature. They have taken away the windows picture viewer and gif images don’t work without extra software.

The switch to box wouldn't let me switch mto moizilla on a download for an upgrade to snagit.

shaneksmith1957@gmail.c

 

4/5/2009 12:19:52 AM

7 crashed while saving a word project and going to open a photo.

shaneksmith1957@gmail.com

4/9/2009 6:17:34 PM

Windows 7 does not like my logitech webcam.

4/18/2009 1:47:39 AM

 

4/19/2009 9:46:20 PM

7 can feel me closing it down. it crashed as i copy program files so I can downgrade to vista.

shaneksmith1957@gmail.com

Installing windows 7 signature edition on 32 bit and 64 bit. I had to wipe the 32 bit because 7 wouldn’t recognize windows 7 RC. Install of fresh 7 took About 40 minutes. From Vista 64 bit 7 copied and saved programs and data of @ 400gb on my lt and @ 80 programs in @ five hours! That was nice!

 

10/10/2009 9:39:53 PM

Wipe 7 32 bit because of ati problem. Starting re install

To ready desktop:

10/10/2009 10:08:59 PM

A wipe did not fix the ati glitch on a reinstall.

 

Windows 7 changed back to windows 7 basic color scheme and the tuner came back on. I had just plugged the tuner into Laptop 2 64bit vista and ati 650 worked. Then all of a sudden the tuner started working again on my 7 lt. Weird coincidence.

10/14/2009 4:21:42 AM

Uninistalling Roxio and using a windows basic or Aero theme in Display settings then re-installing the 650 program over the existing install made the 650 work for me again. I dare not mess with Windows TV tuner!

For those with simple need that don’t need a TV tuner I sugest Windows 7 Ultimate. For those willing to troubleshoot your ATI tuner I also suggest Windows 7 Ultimate!

10/14/2009 11:23:51 PM

A windows 7 update today caused the ati not to work again. It plays but is slow.

10/17/2009 5:16:59 AM

I had to reverrify my activation key on the 32 bit.

I can only network 2 machines that are both on 7.

10/17/2009 10:12:32 PM

A clean uninstall of the 650 then re-install AFTER re-installing roxio fixed it so far.It’s working with roxio now. Roxio’s TV tuner and the ati tuner are working. If you put in ati first before Roxio then Roxio won’t let you install ati.

Hp 7350 photo printer won’t work with hp laptop 64bit and 7 desktop 32bit. No compatible drivers I have found so far have helped.

I can’t figure out how to sort icons in Quick launch with 7.