Image Intensifier: Difference between revisions

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== Generations ==
== Generations ==
The U.S. Army's Night Vision and Electronic Sensors Directorate (NVESD) categorized image intensifiers into four distinct generations. With each generation, a change in the technology has lead to substantial performance improvements.<ref>Night Vision Technologies Handbook https://www.dhs.gov/sites/default/files/publications/NV-Tech-HB_1013-508.pdf</ref>
Although the generation of any given image intensifier will quickly provide a rough understanding of what to expect from it, it is not a replacement for accurate performance parameters (e.g. [[Figure of Merit (FOM)|FOM]], [[Signal-to-Noise Ratio (SNR)|SNR]], [[Gain]]), as these can vary wildly for different image intensifiers of the same generation.
Some manufacturers and retailers use a ''+'' to indicate intra-generational improvements, e.g. ''Gen. 2+''. This practice is not part of the official specification and can be defined differently by anyone.


=== Generation 0 ===
=== Generation 0 ===
Generation 0 was invented in 1929 by a hungarian scientist in the UK. First uses where in  World War II by the Germans, later the Soviets and the Americans.
Generation 0 was invented in 1929 by a hungarian scientist in the UK. First uses where in  World War II by the Germans, later the Soviets and the Americans.


Gen 0 tubes dont have any or only very low gain of a around 10 and thus rely on strong Ir ilumination.
Gen. 0 tubes don't have any or only very low gain of a around 10 and thus rely on strong IR ilumination.


'''Examples of Gen 0 devices'''
'''Examples of Gen 0 devices'''
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=== Generation 1===
=== Generation 1===
Generation 1, developed and patented in the 1960s, improved greatly the Gain to around 1000. This enabled the use of Gen 1 devices under Moonlight conditions without the use of IR ilumination.
Generation 1, developed and patented in the 1960s, improved the gain to around 1000. This enabled the use of Gen. 1 devices under moonlight conditions without the use of IR illumination.


Later developments included Gen 1+. There the glass in the body was replaced with ceramic. The gain was further improved.  
Later developments include the glass in the body being replaced with ceramic, improving the gain even further. These devices are sometimes referred to as Gen. 1+.  


Some devices used multible tubes in a cascade configuration which leads in strong Gain improvements of up to 100,000.
Some devices used multiple tubes in a cascade configuration, leading to improvements in gain of up to 100,000.


'''Examples of Gen 1 devices'''
'''Examples of Gen 1 devices'''
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*PNV57H
*PNV57H


Gen 1 technology is also found in most cheap consumer devices.
Gen. 1 technology is also found in most cheap consumer devices.


===Generation 2===
===Generation 2===


The generation 2 was developed in the 1970s and was the first generation using a [[Microchannel Plate (MCP)]]. During this time, due to drastic inovations in the semiconductor space, the first widespread integration of the [[Power Supply Unit (PSU)|PSU]] with the tube in a single, modern package appears.
The generation 2 was developed in the 1970s and was the first generation using a [[Microchannel Plate (MCP)]]. During this time, due to drastic innovations in the semiconductor space, the first widespread integration of the [[Power Supply Unit (PSU)|PSU]] with the tube in a single, modern package appears. The [[Microchannel Plate (MCP)]] substantially increased the gain.
The [[Microchannel Plate (MCP)]] increased the gain imens.


Generation 2 IIT are produced mainly with either green or white phosphor screens.
Generation 2 IIT are produced mainly with either green or white phosphor screens.
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===Generation 3===
===Generation 3===
{{Unverified}}
{{Unverified}}
The photocathode is made using gallium arsenide and the refined MCP technology is coated with an Aluminium oxide layer called ion barrier film to prolong the tubes functional life by preventing the occasionally released ion to damage the MCP, a process called ion-poisoning which drastically dimishes the plates functional lifespan. The downside of this ion film is that it somewhat restricts the amount of electrons that pass through it thereby detracting some of the intensification. The so called haloing-effect was also increased by this film, something that lessens the practical performance since it may obscure parts of what is being observed.  
The photocathode is made using gallium arsenide and the refined MCP technology is coated with an Aluminum oxide layer called ion barrier film to prolong the tubes functional life by preventing the occasionally released ion to damage the MCP, a process called ion-poisoning which drastically diminishes the plates functional lifespan. The downside of this ion film is that it somewhat restricts the amount of electrons that pass through it thereby detracting some of the intensification. The so called haloing-effect was also increased by this film, something that lessens the practical performance since it may obscure parts of what is being observed.  


Subsequent development of the technology led to ”thin-film” tubes among other solutions to lessen the impact of the ion barrier on gain and resolution. Since the beginnings of thin-film IIT it has become so commonplace that instead of being singled out as having thin ion barrier film the earlier image intensifiers are nowadays referred to as ”thick-film” instead.  
Subsequent development of the technology led to ”thin-film” tubes among other solutions to lessen the impact of the ion barrier on gain and resolution. Since the beginnings of thin-film IIT it has become so commonplace that instead of being singled out as having thin ion barrier film the earlier image intensifiers are nowadays referred to as ”thick-film” instead.  


Gen 3 tubes are manufactured in both green and white phosphor screen versions although some manufacturers have equipped their IITs with other monochromatic and in the case of Adams Industries a bichromatic screen.  
Gen. 3 tubes are manufactured in both green and white phosphor screen versions although some manufacturers have equipped their IITs with other monochromatic and in the case of Adams Industries a bichromatic screen.  


Gain averages between 30k to 50k.
Gain averages between 30k to 50k.
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The only other eastern producer is [[Ekran FEP]].  
The only other eastern producer is [[Ekran FEP]].  
=== Generation 4 ===
The official specification does not include Generation 4, as even the most modern filmless image intensifier tubes still fall under the definition of Generation 3.


== Formats==
== Formats==
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*SwaP (16mm)
*SwaP (16mm)


== References ==
<references />
[[Category:Technology]]
[[Category:Technology]]

Revision as of 13:52, 21 November 2022

An image intensifier (abbreviation: II or I²) is an electro-optical component that can produce an intensified monochrome image on a phosphor screen from a cone of incoming light, intended to intensify the signal beyond what optics and digital sensors are capable of.

In the field of night vision, image intensifier refers to image intensifier tubes which are miniaturized image intensifiers (usually in tubular shape) that form the core component of any night vision device.

Image intensifier tubes are inserted into a housing that otherwise only provides optics, power supply, and protection of the sensitive component. Many formats of image intensifier tubes are designed to be exchangable with limited tooling and know-how, originally intended to allow armies to replace damaged image intensifier tubes by an engineer during deployment.

Generations

The U.S. Army's Night Vision and Electronic Sensors Directorate (NVESD) categorized image intensifiers into four distinct generations. With each generation, a change in the technology has lead to substantial performance improvements.[1]

Although the generation of any given image intensifier will quickly provide a rough understanding of what to expect from it, it is not a replacement for accurate performance parameters (e.g. FOM, SNR, Gain), as these can vary wildly for different image intensifiers of the same generation.

Some manufacturers and retailers use a + to indicate intra-generational improvements, e.g. Gen. 2+. This practice is not part of the official specification and can be defined differently by anyone.

Generation 0

Generation 0 was invented in 1929 by a hungarian scientist in the UK. First uses where in World War II by the Germans, later the Soviets and the Americans.

Gen. 0 tubes don't have any or only very low gain of a around 10 and thus rely on strong IR ilumination.

Examples of Gen 0 devices

  • Vampir
  • M2 & M3 Sniperscope
  • PNV57A

Generation 1

Generation 1, developed and patented in the 1960s, improved the gain to around 1000. This enabled the use of Gen. 1 devices under moonlight conditions without the use of IR illumination.

Later developments include the glass in the body being replaced with ceramic, improving the gain even further. These devices are sometimes referred to as Gen. 1+.

Some devices used multiple tubes in a cascade configuration, leading to improvements in gain of up to 100,000.

Examples of Gen 1 devices

Gen. 1 technology is also found in most cheap consumer devices.

Generation 2

The generation 2 was developed in the 1970s and was the first generation using a Microchannel Plate (MCP). During this time, due to drastic innovations in the semiconductor space, the first widespread integration of the PSU with the tube in a single, modern package appears. The Microchannel Plate (MCP) substantially increased the gain.

Generation 2 IIT are produced mainly with either green or white phosphor screens.

Gain average around 20k.

Examples of Gen 2 devices

  • GN-1 employed Gen 2 IIT upon release.

Generation 3

⚠ This section contains unverified information. You can help by adding references to it.

The photocathode is made using gallium arsenide and the refined MCP technology is coated with an Aluminum oxide layer called ion barrier film to prolong the tubes functional life by preventing the occasionally released ion to damage the MCP, a process called ion-poisoning which drastically diminishes the plates functional lifespan. The downside of this ion film is that it somewhat restricts the amount of electrons that pass through it thereby detracting some of the intensification. The so called haloing-effect was also increased by this film, something that lessens the practical performance since it may obscure parts of what is being observed.

Subsequent development of the technology led to ”thin-film” tubes among other solutions to lessen the impact of the ion barrier on gain and resolution. Since the beginnings of thin-film IIT it has become so commonplace that instead of being singled out as having thin ion barrier film the earlier image intensifiers are nowadays referred to as ”thick-film” instead.

Gen. 3 tubes are manufactured in both green and white phosphor screen versions although some manufacturers have equipped their IITs with other monochromatic and in the case of Adams Industries a bichromatic screen.

Gain averages between 30k to 50k.

Examples of Gen 3 devices

Filmless IIT

Manufacturer L3Harris stands out as the sole western producer of Filmless/Unfilmed (term used interchangeably) tubes due to having patented the process. See relevant section on the manufacturers page for further information.

The only other eastern producer is Ekran FEP.

Generation 4

The official specification does not include Generation 4, as even the most modern filmless image intensifier tubes still fall under the definition of Generation 3.

Formats

References

  1. Night Vision Technologies Handbook https://www.dhs.gov/sites/default/files/publications/NV-Tech-HB_1013-508.pdf
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