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About Night Vision:
The Image Intensifier tube is the most important part of a night vision device. ITT is the largest manufacturer of high-quality and high performance night vision image intensifier tubes. The information below is a courtesy of ITT Industries night vision and represent a straight forward explanation and facts about the night vision.
Night vision technology consists of two major types: light amplification (or intensification) and thermal (infrared).
Most consumer night vision products are light amplifying devices. All ITT Night Vision products use light-amplifying technology. This technology takes the small amount of light that's in the surrounding area (such as moonlight or starlight), and converts the light energy (scientists call it photons) into electrical energy (electrons).
These electrons pass through a thin disk that's about the size of a quarter and contains more than 10 million channels. As the electrons go through the channels, they strike the channel walls and thousands more electrons are released. These multiplied electrons then bounce off of a phosphor screen which converts the electrons back into photons and lets you see an impressive nighttime view even when it's really dark.
The photocathode is coated with sensitive gallium arsenide, which allows for a more efficient conversion of light to electrical energy at extremely low levels of light.
Generation 3 provides the clearest, sharpest night vision image available. The units have a higher-performing image intensifier tube with a minimum 51 lp/mm resolution (typical 64 lp/mm), compared to the 45 lp/mm minimum of a standard Generation 2 unit. Line Pairs per Millimeter (lp/mm) are units used to measure image intensifier resolution; the higher they are, the clearer the image becomes.
Generation 2 marked the development of a microchannel plate, which multiplies the number of electrons by the thousands. This produces a clear image in nighttime situations without the distortion of Gen 0 and Gen 1.
Generation 1 has problems with distortion and short-lived intensifier tubes. It uses materials that are better than Gen 0 to convert light to electrons. These units were able to operate at lower light levels than the Gen 0 and became known as "starlight scopes." Imported night vision viewers usually use Gen 1 image intensifiers even though they may be advertised as Gen 2.
Generation 0 technology depended on external light to increase available light energy. After the light was converted to electrons, electrical components focused these electrons through a cone-shaped device (anode) and accelerated them so they hit the phosphor screen with greater energy, creating the visible image. Unfortunately, accelerating the electrons in this manner caused distortion in the image and decreased the tube's life.
All Generation 3 products sold internationally require an export license from the U.S. Department of State, Office of Defense Trade Controls, in accordance with International Traffic in Arms (ITAR), Title 22, Code of Federal Regulation. Most Generation 2 products are controlled by the U.S. Department of Commerce, Bureau of Export Administration, Commodity List Number 6A002.
Performance Attributes:
There are three important attributes for judging performance. They are: sensitivity, signal and resolution. As the customer, you need to know about these three characteristics to determine the performance level of a night vision system.
Sensitivity, or photoresponse, is the image tube's ability to detect available light. It is usually measured in "uA/lm," or microamperes per lumen.
Signal to Noise ratio plays a key role in night vision performance. ITT's microchannel plate technology is unsurpassed in its ability to transfer a strong signal from input to output. Just as high-end stereo equipment gives you quality sound, ITT Night Vision gives you a quality output image without "noise."
Resolution is the third major consideration when purchasing night vision. This is the ability to resolve detail in your image. High-quality optics and the latest processing methods give ITT Night Vision the edge. Some of our competitors put magnified optics in their systems to give the illusion that they have high resolving systems. In the trade-off, field of view is sacrificed. ITT gives the option of higher magnification only so you can have it if you want it. The system does not need higher magnification to function effectively. Our technology offers a uniquely formulated phosphor screen to create the highest contrasting images, thereby generating the highest resolution products available to the consumer.
Technical Characteristics of Night Vision:
Using intensified night vision is different from using regular binoculars and/or your own eyes. Below are some of the aspects of night vision that you should be aware of when you are using an image intensified night vision system.
Textures, Light and Dark
Objects that appear light during the day but have a dull surface may appear darker through the night vision unit than objects that are dark during the day but have a highly reflective surface. For example, a shiny dark colored jacket may appear brighter than a light colored jacket with a dull surface.
Depth Perception
Night vision does not present normal depth perception.
Fog and Rain Night vision is very responsive to reflective ambient light; therefore, the light reflecting off of fog or heavy rain causes much more light to go toward the night vision unit and may degrade its performance.
Honeycomb*
This is a faint hexagonal pattern, which is the result of the manufacturing process.
Spots*
A few black spots throughout the image area also are inherent characteristics of all night vision technology. These spots will remain constant and should not increase in size or number. See the example below of an image with black spots.
Do not be concerned if you see this feature. It is an inherent characteristic found in light amplification night vision systems that incorporate a microchannel plate in the intensifer.
2007ŠITT Industries
PINNACLE INTENSIFIER TUBE TECHNOLOGY and HISTORY
The story of the Pinnacle began in 1997 when the Army Night Vision Program office awarded two cost-share contracts to ITT and to Litton Electro-Optical Systems, now part of Northrop Grumman, to develop the next generation of image intensification devices, Gen 4 in military parlance.
Specifically, the Army wanted a Gen 4 tube that had no ion barrier, or protective coating, on the micro-channel plate (MCP), a thin glass wafer similar to a fiber-optic faceplate. The MCP is one of the major components of any image intensifier tube that includes the photocathode, a phosphor screen and an integrated power supply. The 18-mm tube, the main technology on which the night vision goggles (NVGs) are based, allows the user to see clearly at night without an active light source.
How does the Pinnacle or any image intensifier tube work? Visible and non-visible visible light from the stars or moon enters the photocathode. That light energy (photons) is converted initially into electrical energy - electrons. The electrons travel from the cathode to the MCP, a wafer with over ten million holes, where they are multiplied hundreds of times. The electrons then travel to the phosphor screen where, with the help of an internal power source, they are converted back into a visible light image.
Years earlier, the addition of a film coating over the input side of the MCP had elevated tube technology to Gen 3 from Gen 2 and increased tube reliability five fold. Attempts to develop filmless Gen 3 tubes had been underway for over a decade and none had achieved the desired reliability standard. Nevertheless, the military and some in the scientific community believed that going filmless was the next logical progression in night vision technology.
Tests revealed that a filmless tube would increase performance of NVGs by 20%, thereby giving U.S. forces a further edge over adversaries. That was the good news. Unfortunately, those same tests revealed immediate degradation of the new tube because there was no film to protect the photocathode from the harmful ions generated during normal tube operation.
ITT engineers doubted whether a Gen 4 tube could even meet the 10,000 hours of active life, standard for Gen 3 devices, like the "Ultra" tube. The "Ultra" tube was unveiled in November 1995 and prompted ITT's receipt of 100% of the Army's 1996 Omni IV contract
Adding the Pinnacle to its the product offering helped vault ITT back to the top and preserve jobs at the Roanoke facility. Equally important was the military's acceptance of the thin-filmed Pinnacle over the filmless tube. In October 2001, Dr. John Pollard, chief scientist for the Army's Night Vision & Electronic Sensors Directorate (NVESD), announced that the term "Gen 4" was being removed as an identifier of filmless tube technology. The move, in effect, tabled indefinitely any plan to procure a filmless tube. The Army now officially uses the term "thin film" - rather than ITT's Pinnacle moniker - to identify this technology advancement.
The Pinnacle won for ITT the major share of the Omni VI procurement because it offered higher performance, longer reliability, and cost savings and because of ITT's proven track record for technology advancements and customer responsiveness. Overall, The Pinnacle combines leading-edge technology and proven reliability to create the "best value" for the military. (copyright ITT Industries)
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