View allAll Photos Tagged Detection
Visual notes from a NIST colloquium by Nergis Mavalvala (MIT) on gravitational wave detection.
Disclaimer: Occasional errors in the content of these notes are mine and may be due to an error I made when writing something down. Such errors do not reflect the intent of the speakers.
Three workers dig to build a camera and seismic station to detect wildfires.
As fire seasons have become longer and more devastating, firefighters have looked to wide variety of technologies to assist with detection and response. The Alert Wildfire detection camera project, which began over a decade ago, was developed in conjunction with the Bureau of Land Management (BLM) Oregon/Washington, BLM Idaho, BLM Nevada, and University of Nevada Reno - Nevada and University of Oregon’s Seismological Laboratories.
In 2004, the University of Nevada Reno developed a stand-alone microwave network to support the change from analog to digital seismic station sensors. The microwave system runs on an unlicensed broadband public safety band that is networked across the states. This system has evolved from just transmitting seismic data, to the current wildfire detection video data from stations and cameras located primarily on BLM-permitted lands.
The cameras and associated tools help firefighters and first responders:
•discover/locate/confirm fire ignition,
•quickly scale fire resources up or down appropriately,
•monitor fire behavior through containment,
•during firestorms, help evacuations through enhanced situational awareness,
•ensure contained fires are monitored appropriately through their demise, and
•view prescribed fires both during ignition and during monitoring stages.
The camera network is fed by a single point mountaintop camera via microwave to central hosting point at the University of Nevada Reno. The cameras are 1080 high definition/high speed with pan, tilt, and zoom capabilities. The cameras also provide a live feed of for designated users of six frames per second.
Cameras provide a remote feed to a web page that updates the pictures every 10 seconds. Over the last several years, this innovative technology has provided critical information for thousands of fires throughout the western U.S.
In Fiscal Year 2022, the Oregon/Washington Bureau of Land Management awarded the University of Oregon (UO) $718,346 to help aid in wildfire prevention by developing the most integrated, and interorganizational wildfire detection system in the United States.
Funding will provide continued statewide access to vital information of emergent wildfires and provide for the most efficient and effective emergency response, thereby ensuring the quality of lives of Oregonians and protecting our natural resources.
In 2022, the BLM helped lead the establishment of an Oregon Statewide Wildfire Detection Camera System with the goal of establishing collaborative governance to establish and implement a statewide wildfire detection camera strategy that addresses a long-term detection camera build-out between the multiple agencies while also addressing current and future detection camera technologies.
The ALERTWildfire program continues to grow, the ability to locate smoke at a very early stage will ultimately allow firefighters more time to assess the situation and mobilize appropriate resources. This unique use of technology will save taxpayers money as well as our forests, grasslands, property, and lives, while managing risk to our firefighters through an informed response.
The 41 wildfire detection cameras covering Oregon and Washington can be viewed online at:
Photo: Fremont-Winema National Forest and BLM Lakeview District.
Event Alarm Detection
Time : 20151102-05:59:28
Camera IP : 192.168.1.135
Event Type : Audio Detection Nov-02-2015 05:59:28 Detected
An Italian soldier masters the Target Detection lane during the European Best Sniper Squad Competition at the 7th Army Training Commandâs, Grafenwoehr Training Area, Bavaria, Germany, Oct. 25, 2016. The European Best Sniper Squad Competition is an Army Europe competition challenging militaries from across Europe to compete and enhance teamwork with Allies and partner nations. (U.S. Army photo by Visual Information Specialist Gertrud Zach)
As part of an IAEA training course on nuclear security, an indoor tour is conducted at Japan’s Physical Protection Exercise Field, part of its Integrated Support Center for Nuclear Nonproliferation and Nuclear Security (ISCN), in Tokai-Mura. ISCN training courses combine classroom learning on key concepts with exercises and demonstrations. Participants gained hands-on experience with real equipment and measures that States employ to strengthen physical protection of nuclear material and facilities. (June 2017)
Japan is a member of the International Network for Nuclear Security Training and Support Centres (NSSC Network), which was established by IAEA Member States in 2012 to facilitate sharing of information and resources and to promote coordination and collaboration among states with an NSSC or those having an interest in developing a centre. The 2018 NSSC Network Annual Meeting will be hosted at ISCN, 5 – 9 March 2018.
Photo Credit: Dean Calma / IAEA
LECTURERS:
Nicolas Daniel Delaunay
Institute for Radiological Protection and Nuclear Safety
Axel Hagemann
IAEA Consultant from Germany
Miroslav Gregoric
From Slovenia
Reina Matsuzawa
ISCN, Japan Atomic Energy Agency
Yo Nakamura
ISCN, Japan Atomic Energy Agency
IAEA OFFICERS:
Shigeaki Sato
IAEA Nuclear Security Officer
Division of Nuclear Security
Department of Nuclear Safety and Security
Danielle Dahlstrom
IAEA Outreach Nuclear Security Officer
Division of Nuclear Security
Department of Nuclear Safety and Security
(•) – The Lockheed Martin HC-130J Hercules The Combat King II is the U.S. Air Force's only dedicated fixed-wing personnel recovery platform and is flown by the Air Education and Training Command (AETC) and Air Combat Command (ACC). This C-130J variation specializes in tactical profiles and avoiding detection and recovery operations in austere environments. The HC-130J replaces HC-130P/Ns as the only dedicated fixed-wing Personnel Recovery platform in the Air Force inventory. It is an extended-range version of the C-130J Hercules transport. Its mission is to rapidly deploy to execute combatant commander directed recovery operations to austere airfields and denied territory for expeditionary, all weather personnel recovery operations to include airdrop, airland, helicopter air-to-air refueling, and forward area ground refueling missions. When tasked, the aircraft also conducts humanitarian assistance operations, disaster response, security cooperation/aviation advisory, emergency aeromedical evacuation, and noncombatant evacuation operations.
Features
Modifications to the HC-130J have improved navigation, threat detection and countermeasures systems. The aircraft fleet has a fully-integrated inertial navigation and global positioning systems, and night vision goggle, or NVG, compatible interior and exterior lighting. It also has forward-looking infrared, radar and missile warning receivers, chaff and flare dispensers, satellite and data-burst communications, and the ability to receive fuel inflight via a Universal Aerial Refueling Receptacle Slipway Installation (UARRSI).
The HC-130J can fly in the day; however, crews normally fly night at low to medium altitude levels in contested or sensitive environments, both over land or overwater. Crews use NVGs for tactical flight profiles to avoid detection to accomplish covert infiltration/exfiltration and transload operations. To enhance the probability of mission success and survivability near populated areas, crews employ tactics that include incorporating no external lighting or communications, and avoiding radar and weapons detection.
Drop zone objectives are done via personnel drops and equipment drops. Rescue bundles include illumination flares, marker smokes and rescue kits. Helicopter air-to-air refueling can be conducted at night, with blacked out communication with up to two simultaneous helicopters. Additionally, forward area refueling point operations can be executed to support a variety of joint and coalition partners.
Background
The HC-130J is a result of the HC/MC-130 recapitalization program and replaces Air Combat Command's aging HC-130P/N fleet as the dedicated fixed-wing personnel recovery platform in the Air Force inventory. The 71st and 79th Rescue Squadrons in Air Combat Command, the 550th Special Operations Squadron in Air Education and Training Command, the 920th Rescue Group in Air Force Reserve Command and the 106th Rescue Wing, 129th RQW and 176th Wing in the Air National Guard will operate the aircraft.
First flight was 29 July 2010, and the aircraft will serve the many roles and missions of the HC-130P/Ns. It is a modified KC-130J aircraft designed to conduct personnel recovery missions, provide a command and control platform, in-flight-refuel helicopters and carry supplemental fuel for extending range or air refueling.
In April 2006, the personnel recovery mission was transferred back to Air Combat Command at Langley AFB, Va. From 2003 to 2006, the mission was under the Air Force Special Operations Command at Hurlburt Field, Fla. Previously, HC-130s were assigned to ACC from 1992 to 2003. They were first assigned to the Air Rescue Service as part of Military Airlift Command.
General Characteristics
Primary function: Fixed-wing Personnel Recovery platform
Contractor: Lockheed Aircraft Corp.
Power Plant: Four Rolls Royce AE2100D3 turboprop engines
Thrust: 4,591 Propeller Shaft Horsepower, each engine
Wingspan: 132 feet, 7 inches (40.4 meters)
Length: 97 feet, 9 inches (29.57 meters)
Height: 38 feet, 9 inches (11.58 meters)
Operating Weight: 89,000 pounds (40,369 kilograms)
Maximum Takeoff Weight: 164,000 pounds (74,389 kilograms)
Fuel Capacity: 61,360 pounds (9,024 gallons)
Payload: 35,000 pounds (15,875 kilograms)
Speed: 316 knots indicated air speed at sea level
Range: beyond 4,000 miles (3,478 nautical miles)
Ceiling: 33,000 feet (10,000 meters)
Armament: countermeasures/flares, chaff
Basic Crew: Three officers (pilot, co-pilot, combat system officer) and two enlisted loadmasters
Unit Cost: $66 million (fiscal 2010 replacement cost)
Initial operating capability: 2013.
(•) – The Sikorsky MH-60G/HH-60G Pave Hawk is a twin turboshaft engine helicopter in service with the United States Air Force. It is a derivative of the UH-60 Black Hawk and incorporates the US Air Force PAVE electronic systems program. The HH-60/MH-60 is a member of the Sikorsky S-70 family.
The MH-60G Pave Hawk's primary mission is insertion and recovery of special operations personnel, while the HH-60G Pave Hawk's core mission is recovery of personnel under stressful conditions, including search and rescue. Both versions conduct day or night operations into hostile environments. Because of its versatility, the HH-60G may also perform peace-time operations such as civil search and rescue, emergency aeromedical evacuation (MEDEVAC), disaster relief, international aid and counter-drug activities.
PNNL's biomonitoring detection system uses two classes of sensors to analyze blood, urine or saliva samples. While small and portable, the sensitive system provides detection levels at parts-per-billion.
Terms of Use: Our images are freely and publicly available for use with the credit line, "Courtesy of Pacific Northwest National Laboratory." Please use provided caption information for use in appropriate context.
Detection of the color disks with the USB FT camera. The camera is mounted on the pic an place robot arm. It is set to image a zone of 4x4 discs. The table consists of 8 of these modules. By taking 8 images the whole surface can be measured. In total, there can be up to 128 color disks. The camera must also detect if there are any unused areas. Once all 8 blocks have been recorded, the entire drawing can be displayed on the 128 neo-led pixel display. The drawing can then be stored in the flash memory for later automatic remaking by the pic and plcae robot. The grandchildren can then manually make and save a drawing.
The table shows the RGB and W values of 16 measured zones (C0 .. C15). The task is now to calculate the correct color from these values.
Detectie van de kleur schijfjes met de USB FT camera. De camera is gemonteerd op de pic an place robot arm. Hij is zo ingesteld dat hij een zone van 4x4 schijfjes in beeld neemt. De tabel bestaat uit 8 van deze modules. Door 8 beelden te nemen kan de ganse oppervlakte opgemeten worden. In totaal kunnen er max 128 schijfjes zijn. De camera moet ook detecteren of er ongebruikte plaatsen zijn. Eens alle 8 blokken opgenomen zijn kan de volledige tekening weergegeven worden op de 128 neo-led pixel display. De tekening kan daarna in het flash geheugen opgeslagen worden om later opnieuw automatisch door de pic and plcae robot te hermaken. De kleinkinderen kunnen zo zelf manueel een tekening aanbrengen en opslaan
De tabel geeft de RGB en W waarde weer van 16 opgemeten zones (C0 .. C15). De opdracht is nu om uit deze waarden de juiste kleur te berekenen.
One of our QDC #MetalDetectors installed in a #recycling operation to identify large tramp metal prior to shredding and prevent serious & costly damage | find out more www.mastermagnets.com/metal-detection/belt-conveyor-metal...
As part of an IAEA training course on nuclear security, an indoor tour is conducted at Japan’s Physical Protection Exercise Field, part of its Integrated Support Center for Nuclear Nonproliferation and Nuclear Security (ISCN), in Tokai-Mura. ISCN training courses combine classroom learning on key concepts with exercises and demonstrations. Participants gained hands-on experience with real equipment and measures that States employ to strengthen physical protection of nuclear material and facilities. (June 2017)
Japan is a member of the International Network for Nuclear Security Training and Support Centres (NSSC Network), which was established by IAEA Member States in 2012 to facilitate sharing of information and resources and to promote coordination and collaboration among states with an NSSC or those having an interest in developing a centre. The 2018 NSSC Network Annual Meeting will be hosted at ISCN, 5 – 9 March 2018.
Photo Credit: Dean Calma / IAEA
LECTURERS:
Nicolas Daniel Delaunay
Institute for Radiological Protection and Nuclear Safety
Axel Hagemann
IAEA Consultant from Germany
Miroslav Gregoric
From Slovenia
Reina Matsuzawa
ISCN, Japan Atomic Energy Agency
Yo Nakamura
ISCN, Japan Atomic Energy Agency
IAEA OFFICERS:
Shigeaki Sato
IAEA Nuclear Security Officer
Division of Nuclear Security
Department of Nuclear Safety and Security
Danielle Dahlstrom
IAEA Outreach Nuclear Security Officer
Division of Nuclear Security
Department of Nuclear Safety and Security
Detection of the color disks with the USB FT camera. The camera is mounted on the pic an place robot arm. It is set to image a zone of 4x4 discs. The table consists of 8 of these modules. By taking 8 images the whole surface can be measured. In total, there can be up to 128 color disks. The camera must also detect if there are any unused areas. Once all 8 blocks have been recorded, the entire drawing can be displayed on the 128 neo-led pixel display. The drawing can then be stored in the flash memory for later automatic remaking by the pic and plcae robot. The grandchildren can then manually make and save a drawing.
The table shows the RGB and W values of 16 measured zones (C0 .. C15). The task is now to calculate the correct color from these values.
Detectie van de kleur schijfjes met de USB FT camera. De camera is gemonteerd op de pic an place robot arm. Hij is zo ingesteld dat hij een zone van 4x4 schijfjes in beeld neemt. De tabel bestaat uit 8 van deze modules. Door 8 beelden te nemen kan de ganse oppervlakte opgemeten worden. In totaal kunnen er max 128 schijfjes zijn. De camera moet ook detecteren of er ongebruikte plaatsen zijn. Eens alle 8 blokken opgenomen zijn kan de volledige tekening weergegeven worden op de 128 neo-led pixel display. De tekening kan daarna in het flash geheugen opgeslagen worden om later opnieuw automatisch door de pic and plcae robot te hermaken. De kleinkinderen kunnen zo zelf manueel een tekening aanbrengen en opslaan
De tabel geeft de RGB en W waarde weer van 16 opgemeten zones (C0 .. C15). De opdracht is nu om uit deze waarden de juiste kleur te berekenen.
Surveying for contamination using a radiation detection device. (Nov. 2007)
Visit the Nuclear Regulatory Commission's website at www.nrc.gov/.
To comment on this photo go to public-blog.nrc-gateway.gov/2012/04/01/nrc-moves-its-publ....
Event Alarm Detection
Time : 20151010-14:49:13
Camera IP : 192.168.1.134
Event Type : Audio Detection Oct-10-2015 14:49:13 Detected
Date: 2011 MAY 29
Time: 11H15
Temperature: 20 degree
Location: Belgium, Oostrozebeke.
Nikon D300, AF105/2.8D macro lens.
Optical laser detection for focus.
For the setup of this DIY capture unit see:
www.flickr.com/photos/fotoopa_hs/5312347017/
As part of an IAEA training course on nuclear security, an indoor tour is conducted at Japan’s Physical Protection Exercise Field, part of its Integrated Support Center for Nuclear Nonproliferation and Nuclear Security (ISCN), in Tokai-Mura. ISCN training courses combine classroom learning on key concepts with exercises and demonstrations. Participants gained hands-on experience with real equipment and measures that States employ to strengthen physical protection of nuclear material and facilities. (June 2017)
Japan is a member of the International Network for Nuclear Security Training and Support Centres (NSSC Network), which was established by IAEA Member States in 2012 to facilitate sharing of information and resources and to promote coordination and collaboration among states with an NSSC or those having an interest in developing a centre. The 2018 NSSC Network Annual Meeting will be hosted at ISCN, 5 – 9 March 2018.
Photo Credit: Dean Calma / IAEA
LECTURERS:
Nicolas Daniel Delaunay
Institute for Radiological Protection and Nuclear Safety
Axel Hagemann
IAEA Consultant from Germany
Miroslav Gregoric
From Slovenia
Reina Matsuzawa
ISCN, Japan Atomic Energy Agency
Yo Nakamura
ISCN, Japan Atomic Energy Agency
IAEA OFFICERS:
Shigeaki Sato
IAEA Nuclear Security Officer
Division of Nuclear Security
Department of Nuclear Safety and Security
Danielle Dahlstrom
IAEA Outreach Nuclear Security Officer
Division of Nuclear Security
Department of Nuclear Safety and Security
LAPD PO3 Thomas Davoren Bomb Detection K9 Handler & Crown Victoria @ Wings Wheels and Rotors Airshow
As part of an IAEA training course on nuclear security, an indoor tour is conducted at Japan’s Physical Protection Exercise Field, part of its Integrated Support Center for Nuclear Nonproliferation and Nuclear Security (ISCN), in Tokai-Mura. ISCN training courses combine classroom learning on key concepts with exercises and demonstrations. Participants gained hands-on experience with real equipment and measures that States employ to strengthen physical protection of nuclear material and facilities. (June 2017)
Japan is a member of the International Network for Nuclear Security Training and Support Centres (NSSC Network), which was established by IAEA Member States in 2012 to facilitate sharing of information and resources and to promote coordination and collaboration among states with an NSSC or those having an interest in developing a centre. The 2018 NSSC Network Annual Meeting will be hosted at ISCN, 5 – 9 March 2018.
Photo Credit: Dean Calma / IAEA
LECTURERS:
Nicolas Daniel Delaunay
Institute for Radiological Protection and Nuclear Safety
Axel Hagemann
IAEA Consultant from Germany
Miroslav Gregoric
From Slovenia
Reina Matsuzawa
ISCN, Japan Atomic Energy Agency
Yo Nakamura
ISCN, Japan Atomic Energy Agency
IAEA OFFICERS:
Shigeaki Sato
IAEA Nuclear Security Officer
Division of Nuclear Security
Department of Nuclear Safety and Security
Danielle Dahlstrom
IAEA Outreach Nuclear Security Officer
Division of Nuclear Security
Department of Nuclear Safety and Security
Coast Guard Petty Officer 1st Class Christopher Hartman, from Maritime Safety and Security Team San Francisco, and his dog Evy conduct training in AT&T Park in San Francisco Thursday, March 27, 2014. Explosive detection dogs, like Evy, conduct annual training aimed at measuring the dogs' ability to detect bomb-making materials. U.S. Coast Guard photo by Petty Officer 3rd Class Adam Stanton
The IAEA conducts a national workshop on nuclear security in Victoria Falls, bringing together authorities from the Office of the President and Cabinet, the Radiation Protection Authority, the Zimbabwe Revenue Authority and others, to view and strengthen national nuclear security detection strategies and measures in Zimbabwe. Victoria Falls, Zimbabwe. 10 October 2016.
Participants break into groups to discuss and finalize national detection strategies for nuclear and other radioactive material out of regulatory control. Different operational scenarios informed their discussion and exchange of information.
Photo Credit: Dean Calma / IAEA
Leak Masters USA offers pool leak detection and repair services for your residential or commercial pool. Visit our site at www.leakmastersusa.com
As part of an IAEA training course on nuclear security, an indoor tour is conducted at Japan’s Physical Protection Exercise Field, part of its Integrated Support Center for Nuclear Nonproliferation and Nuclear Security (ISCN), in Tokai-Mura. ISCN training courses combine classroom learning on key concepts with exercises and demonstrations. Participants gained hands-on experience with real equipment and measures that States employ to strengthen physical protection of nuclear material and facilities. (June 2017)
Japan is a member of the International Network for Nuclear Security Training and Support Centres (NSSC Network), which was established by IAEA Member States in 2012 to facilitate sharing of information and resources and to promote coordination and collaboration among states with an NSSC or those having an interest in developing a centre. The 2018 NSSC Network Annual Meeting will be hosted at ISCN, 5 – 9 March 2018.
Photo Credit: Dean Calma / IAEA
LECTURERS:
Nicolas Daniel Delaunay
Institute for Radiological Protection and Nuclear Safety
Axel Hagemann
IAEA Consultant from Germany
Miroslav Gregoric
From Slovenia
Reina Matsuzawa
ISCN, Japan Atomic Energy Agency
Yo Nakamura
ISCN, Japan Atomic Energy Agency
IAEA OFFICERS:
Shigeaki Sato
IAEA Nuclear Security Officer
Division of Nuclear Security
Department of Nuclear Safety and Security
Danielle Dahlstrom
IAEA Outreach Nuclear Security Officer
Division of Nuclear Security
Department of Nuclear Safety and Security
As a leading software development firm in the United States. We have reached a new level of productivity to create highly proficient, technologically advanced and functionally superior face detection software system to extend the security level.
The IAEA conducts a national workshop on nuclear security in Victoria Falls, bringing together authorities from the Office of the President and Cabinet, the Radiation Protection Authority, the Zimbabwe Revenue Authority and others, to view and strengthen national nuclear security detection strategies and measures in Zimbabwe. Victoria Falls, Zimbabwe. 10 October 2016.
Participants break into groups to discuss and finalize national detection strategies for nuclear and other radioactive material out of regulatory control. Different operational scenarios informed their discussion and exchange of information.
Photo Credit: Dean Calma / IAEA
Side Event at the IAEA International Conference on the Security of Radioactive Material: The Way Forward for Prevention and Detection. IAEA, Vienna, Austria. 4 December 2018
Safety and Security of Radioactive Sources: New Guidance on the Management of Disused Sources
Moderator:
Rene Schlee, IAEA Nuclear Security Officer, Division of Nuclear Security, Department of Nuclear Safety and Security
Opening Remarks:
Muhammad Khaliq, IAEA Section Head, Division of Nuclear Security
Panelist:
Mr. Ruslana Trypailo (Ukraine)
Mr. Jorge Paredes Gilisman (Cuba)
Mr. Mohammed Ali Mogahed Mahmoud (Sudan)
Closing Remarks:
Hilaire Mansoux, IAEA Section Head, Division of Radiation, Transport and Waste Safety
Organized by the IAEA Division of Nuclear Security
The side event will highlight the need and direct benefit for Member States to make a political commitment to the Code and its supplementary guidance; and will provide case studies of State’s successful implementation of its key provision, international cooperation and key actions, as well as promote the guidance as a key international instrument to strengthen the safety and security of radioactive sources globally.
Photo Credit: Dean Calma / IAEA
Justin Hugh Mupamhanga, Deputy Chief Secretary, Office of the President and Cabinet of Zimbabwe, officiates the opening of the national workshop on nuclear security in Victoria Falls, attended by authorities from the Office of the President and Cabinet, the Radiation Protection Authority, the Zimbabwe Revenue Authority, Civil Aviation Authority of Zimbabwe and others, to view and strengthen national nuclear security detection strategies and measures in Zimbabwe. Victoria Falls, Zimbabwe. 11 October 2016.
from left to right: Noor Fitriah Bakri, Nuclear Security Officer, Division of Nuclear Security, Department of Nuclear Safety and Security, Justin Hugh Mupamhanga and Reward Severa, Chief Executive Officer, Radiation Protection Authority of Zimbabwe.
Photo Credit: Dean Calma / IAEA
Side Event at the IAEA International Conference on the Security of Radioactive Material: The Way Forward for Prevention and Detection. IAEA, Vienna, Austria. 4 December 2018
Safety and Security of Radioactive Sources: New Guidance on the Management of Disused Sources
Moderator:
Rene Schlee, IAEA Nuclear Security Officer, Division of Nuclear Security, Department of Nuclear Safety and Security
Opening Remarks:
Muhammad Khaliq, IAEA Section Head, Division of Nuclear Security
Panelist:
Mr. Ruslana Trypailo (Ukraine)
Mr. Jorge Paredes Gilisman (Cuba)
Mr. Mohammed Ali Mogahed Mahmoud (Sudan)
Closing Remarks:
Hilaire Mansoux, IAEA Section Head, Division of Radiation, Transport and Waste Safety
Organized by the IAEA Division of Nuclear Security
The side event will highlight the need and direct benefit for Member States to make a political commitment to the Code and its supplementary guidance; and will provide case studies of State’s successful implementation of its key provision, international cooperation and key actions, as well as promote the guidance as a key international instrument to strengthen the safety and security of radioactive sources globally.
Photo Credit: Dean Calma / IAEA
Disease Detection Stock Photo
When using this photo on a website, please include an image credit for www.ekgtechniciansalary.org.
For Example: [Photo credit: EKG Technician Salary]
LAPD Bomb Squad Bomb Detection K9 Ford F150 @ 2010 LAPD Pacific Division open house and carnival
Unit supervisors vehicle.
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(•) – The Lockheed Martin HC-130J Hercules The Combat King II is the U.S. Air Force's only dedicated fixed-wing personnel recovery platform and is flown by the Air Education and Training Command (AETC) and Air Combat Command (ACC). This C-130J variation specializes in tactical profiles and avoiding detection and recovery operations in austere environments. The HC-130J replaces HC-130P/Ns as the only dedicated fixed-wing Personnel Recovery platform in the Air Force inventory. It is an extended-range version of the C-130J Hercules transport. Its mission is to rapidly deploy to execute combatant commander directed recovery operations to austere airfields and denied territory for expeditionary, all weather personnel recovery operations to include airdrop, airland, helicopter air-to-air refueling, and forward area ground refueling missions. When tasked, the aircraft also conducts humanitarian assistance operations, disaster response, security cooperation/aviation advisory, emergency aeromedical evacuation, and noncombatant evacuation operations.
Features
Modifications to the HC-130J have improved navigation, threat detection and countermeasures systems. The aircraft fleet has a fully-integrated inertial navigation and global positioning systems, and night vision goggle, or NVG, compatible interior and exterior lighting. It also has forward-looking infrared, radar and missile warning receivers, chaff and flare dispensers, satellite and data-burst communications, and the ability to receive fuel inflight via a Universal Aerial Refueling Receptacle Slipway Installation (UARRSI).
The HC-130J can fly in the day; however, crews normally fly night at low to medium altitude levels in contested or sensitive environments, both over land or overwater. Crews use NVGs for tactical flight profiles to avoid detection to accomplish covert infiltration/exfiltration and transload operations. To enhance the probability of mission success and survivability near populated areas, crews employ tactics that include incorporating no external lighting or communications, and avoiding radar and weapons detection.
Drop zone objectives are done via personnel drops and equipment drops. Rescue bundles include illumination flares, marker smokes and rescue kits. Helicopter air-to-air refueling can be conducted at night, with blacked out communication with up to two simultaneous helicopters. Additionally, forward area refueling point operations can be executed to support a variety of joint and coalition partners.
Background
The HC-130J is a result of the HC/MC-130 recapitalization program and replaces Air Combat Command's aging HC-130P/N fleet as the dedicated fixed-wing personnel recovery platform in the Air Force inventory. The 71st and 79th Rescue Squadrons in Air Combat Command, the 550th Special Operations Squadron in Air Education and Training Command, the 920th Rescue Group in Air Force Reserve Command and the 106th Rescue Wing, 129th RQW and 176th Wing in the Air National Guard will operate the aircraft.
First flight was 29 July 2010, and the aircraft will serve the many roles and missions of the HC-130P/Ns. It is a modified KC-130J aircraft designed to conduct personnel recovery missions, provide a command and control platform, in-flight-refuel helicopters and carry supplemental fuel for extending range or air refueling.
In April 2006, the personnel recovery mission was transferred back to Air Combat Command at Langley AFB, Va. From 2003 to 2006, the mission was under the Air Force Special Operations Command at Hurlburt Field, Fla. Previously, HC-130s were assigned to ACC from 1992 to 2003. They were first assigned to the Air Rescue Service as part of Military Airlift Command.
General Characteristics
Primary function: Fixed-wing Personnel Recovery platform
Contractor: Lockheed Aircraft Corp.
Power Plant: Four Rolls Royce AE2100D3 turboprop engines
Thrust: 4,591 Propeller Shaft Horsepower, each engine
Wingspan: 132 feet, 7 inches (40.4 meters)
Length: 97 feet, 9 inches (29.57 meters)
Height: 38 feet, 9 inches (11.58 meters)
Operating Weight: 89,000 pounds (40,369 kilograms)
Maximum Takeoff Weight: 164,000 pounds (74,389 kilograms)
Fuel Capacity: 61,360 pounds (9,024 gallons)
Payload: 35,000 pounds (15,875 kilograms)
Speed: 316 knots indicated air speed at sea level
Range: beyond 4,000 miles (3,478 nautical miles)
Ceiling: 33,000 feet (10,000 meters)
Armament: countermeasures/flares, chaff
Basic Crew: Three officers (pilot, co-pilot, combat system officer) and two enlisted loadmasters
Unit Cost: $66 million (fiscal 2010 replacement cost)
Initial operating capability: 2013.
(•) – The Sikorsky MH-60G/HH-60G Pave Hawk is a twin turboshaft engine helicopter in service with the United States Air Force. It is a derivative of the UH-60 Black Hawk and incorporates the US Air Force PAVE electronic systems program. The HH-60/MH-60 is a member of the Sikorsky S-70 family.
The MH-60G Pave Hawk's primary mission is insertion and recovery of special operations personnel, while the HH-60G Pave Hawk's core mission is recovery of personnel under stressful conditions, including search and rescue. Both versions conduct day or night operations into hostile environments. Because of its versatility, the HH-60G may also perform peace-time operations such as civil search and rescue, emergency aeromedical evacuation (MEDEVAC), disaster relief, international aid and counter-drug activities.
Event Alarm Detection
Time : 20151011-20:59:48
Camera IP : 192.168.1.134
Event Type : Audio Detection Oct-11-2015 20:59:48 Detected
LAPD Bomb Squad Bomb Detection K9 Crown Victoria @ 2010 LAPD Pacific Division open house and carnival
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Respect photographers rights!
Technology
Rep. Alexandria Ocasio-Cortez slammed Amazon for what she characterized as "bias" in the tech giant's facial detection technology.
International Conference on the Security of Radioactive Material: The Way Forward for Prevention and Detection. IAEA, Vienna, Austria. 5 December 2018
Panel Session 3: Detecting Radioactive Material involved in Criminal and Unauthorized Acts
Photo Credit: Dean Calma / IAEA
Moderator:
Victor Evans, UK
Invited Speakers:
Federico Cáceres, Argentina Ministry of Energy and Minerals
Said Abousahl, European Commission Joint Research Centre
Theodoros Matikas, Greece Greek Atomic Energy Commission
Noor Fitriah Binti Bakri, Malaysia Atomic Energy Licensing Board
Na Li, People’s Republic of China
Lynn Ninsiima, Uganda Atomic Energy Council
Richard Papas, USA US Department of Energy
IAEA TEchnical Officer:
Anne McQuaid
Staff Sgt. Dale Dukart, with the North Dakota National Guard’s 81st Civil Support Team, left, places radiation detection equipment next to a vehicle with Kelly Crandall, from the Department of Energy, as Sgt. Kelly Poston, with the Minnesota National Guard’s 55th Civil Support Team, documents the readings at field level of the FargoDome Aug. 13, 2013, in Fargo, N.D., during a training sweep of the arena for radiation. The weeklong training exercise incorporates about three dozen federal, state, local and private agencies working together in the scenario-based response. The sweeps are a routine precaution for large events to protect people in attendance from possible terrorist attacks. (U.S. Air National Guard photo by SMSgt. David H. Lipp/Released)
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Event Alarm Detection
Time : 20151007-20:00:56
Camera IP : 192.168.1.134
Event Type : Audio Detection Oct-07-2015 20:00:56 Detected
The threat of aerial bombardment and gas attacks at the outbreak of the second world war, led to the early distribution of air raid shelters and gas masks.
Accession number: 1979 F90
On the sidelines of the 64th General Conference, the IAEA and the Atomic Energy Licensing Board of Malaysia (AELB) sign an agreement to establish a loaner pool of radiation detection equipment, with contributions from Japan, to support nuclear security training and detection capabilities at major public events in the Asia and Pacific region.
Raja Abdul Aziz Raja Adnan, Director of the IAEA Division of Nuclear Security and Mohd Pauzi Mohd Sobari, Director General of the Atomic Energy Licensing Board in Malaysia signed copies of the agreement via a virtual ceremony. The signing at the IAEA headquarters in Vienna was attended by Juan Carlos Lentijo, Deputy Director General of the IAEA Department of Safety and Security, Ganeson Sivagurunathan, Ambassador of Malaysia, and Atsushi Kuwabara, Minister at the Permanent Mission of Japan to the IAEA. Vienna, Austria. 25 September 2020
Photo credit: Inna Pletukhina / IAEA
Obstacle detection device was a hindrance, so I ask my friend to borrow his stepladder and took photos by using it.
From scientific breeding and puppy development to training, evaluation and research, Auburn University’s Canine Performance Sciences program has one goal: creating the ultimate detection dog to defend the nation.
AN INTEGRATED INJECTION-SEPARATION-DETECTION SYSTEM ON A 2.5 BY 4-CENTIMETER SUBSTRATE.
LLNL ENGINEERS ARE WORKING AT THE UNIVERSITY OF TEXAS M.D. ANDERSON CANCER CENTER, SPONSORED BY THE DEFENSE ADVANCED RESEARCH PROJECTS AGENCY, TO DEVELOP AN INSTRUMENT THAT INCORPORATES NEW TECHNOLOGIES FOR SEPARATING PARTICLES, (KNOWN AS FRACTIONATION) SENSING THEM AND IDENTIFYING THEM BASED ON THEIR DIELECTRIC PROPERTIES. ITS FIRST USE WILL BE TO PERFORM DIFFERENTIAL CELL ANALYSIS ON BLOOD SAMPLES.
For more information or additional images, please contact 202-586-5251.
A unique low-level counting facility at Pacific Northwest Laboratory was internationally recognized for complex radiation detection. The facility was equipped with more than 50 varieties of sensitive detection instruments, most of them developed at PNL, with elite capabilities for nondestructively assaying samples both diverse in size and isotope count.
Terms of Use: Our images are freely and publicly available for use with the credit line, "Courtesy of Pacific Northwest National Laboratory"; Please use provided caption information for use in appropriate context.
Juan Carlos Lentijo, IAEA Deputy Director General and Head of the Department of Nuclear Safety and Security, delivers his opening statement at the International Conference on the Security of Radioactive Material: The Way Forward for Prevention and Detection, held at the Agency headquarters in Vienna, Austria on 3 December 2018
Photo Credit: Dean Calma / IAEA