Israel bars AESA radar export to India

sandeepdg

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In my previous post I had said that the RBE2-AA is, according to me the best option for India for its AESA platform, but the question is whether it can fit a light weight fighter like the LCA, considering its intended for the Rafale which is almost 5 tons heavier than the LCA.
 

Rahul Singh

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In my previous post I had said that the RBE2-AA is, according to me the best option for India for its AESA platform, but the question is whether it can fit a light weight fighter like the LCA, considering its intended for the Rafale which is almost 5 tons heavier than the LCA.
It's the size of the nose cone which will decide if it can be or not? And as i can see, LCA's nose is more 'central African' than 'caucasian'.

PS: no racial intentions in my post.
 

sandeepdg

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It's the size of the nose cone which will decide if it can be or not? And as i can see, LCA's nose is more 'central African' than 'caucasian'.

PS: no racial intentions in my post.
Yes that, as well as the weight of the radar. By the way, I read somewhere that the Elta 2052 weighs around 70-100 kgs for different variants of the radar. But I couldn't find the weight of the RBE2-AA. Also, do you have any idea of the nose cone diameters of LCA, I found on a forum that the nose cone diameter of Rafale is 55cm, though I don't know whether this is correct or not.
 

Anshu Attri

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GaN HEMT Technology for Next-generation Mobile Phone Base Station Amplifiers

http://www.fujitsu.com/global/news/pr/archives/month/2005/20051205-02.html

Fujitsu Laboratories Limited today announced the development of the world's first gallium nitride(1) (GaN) high electron-mobility transistor (HEMT)(2) with insulated gates(3) capable of practical output levels of 100 watts (W) or higher. By reducing gate leakage current to less than one-one millionth that of conventional levels, the technology paves the way for high-efficiency operation of high power GaN HEMTs for amplifiers of next-generation mobile phone base stations.
Fujitsu's new technology will play an important role in reducing power consumption of transmission amplifiers used in next- and future-generation mobile phone base station systems.
Details of this technology will be presented at the IEEE International Electron Devices Meeting (IEDM) to be held in Washington, D.C. from December 5.
Background
As transmission speeds are becoming faster for wireless communications, the power consumption of mobile phone base stations will increase. In order to realize base stations with lower power consumption, GaN HEMT amplifiers are currently being developed. Next- and future-generation networks will have greater output levels, necessitating much higher power efficiency to dramatically reduce the increased power consumption. However, applying existing GaN HEMT technology to reduce power consumption had proven problematic due to the fact that gate leakage current increases as power efficiency rises, creating problems in terms of reliability and amplification characteristics.
Technological Challenges
To improve the gate leakage current, there is a method which employs the insertion of an insulation layer directly below the gate. However, this results in the formation of a very large area in which electron movement is impaired, known as the "interface trap(4)" region, resulting from the surface contact between the insulation layer and semiconductor. This in turn impaired the amplification of the electrical signal applied at the gate electrode and degraded the transistor's output characteristics. As a result, no output beyond 100W could be obtained thus far. This is attributable to the fact that the semiconductor surface in contact with the insulation layer used a layer of aluminum gallium nitride (AlGaN), which contains aluminum. Aluminum oxidizes easily, which leads to degradation of performance.
Newly Developed Technology
Fujitsu succeeded in overcoming the technological obstacles by modifying the surface structure of GaN HEMT. This transistor (patent pending) consists of insulated film of silicon nitride deposited on the outermost layer of a GaN HEMT crystal, that has a thin film of n-type doped GaN. By using a GaN layer for the semiconductor surface, instead of an AlGaN layer, which was conventionally used with insulated gate transistors, Fujitsu succeeded in preventing oxidation of the aluminum surface.
Results
Fujitsu succeeded in reducing gate leakage current to 0.1 microampere or less, which is less than one-one millionth that of conventional technologies that do not use insulated gates.
Performance was also improved, with maximum output of 110 W achieved. This is the world's first insulated gate HEMT capable of producing output of over 100W, attributable to the reduction of the interface trap region. In conjunction with the distortion-compensation circuits(5) that are essential for base station amplifiers, Fujitsu was able to verify that is was possible to lower the value of output power leakage into adjacent channels to practical levels(6). This is the world's first insulated gate HEMT for which distortion characteristics have been proven.
Because this insulated gate technology can operate across the band of maximum efficiency, by combining this new technology with the development of next-generation distortion circuits for high-efficiency ranges, it paves the way for significant power savings for transmission amplifiers.
Future Developments
Fujitsu intends to adapt this technology to its production process and develop GaN-HEMT devices for use in next- and future-generation base station systems.










Glossary
1 Gallium nitride:
A type of wide band-gap semiconductor that is more resistant to breakdown at a given voltage than conventional semiconductors, such as silicon or gallium arsenide.
2 High electron-mobility transistor (HEMT):
A field-effect transistor that takes advantage of operation of the electron layer at the boundary between different semiconductor materials that is relatively rapid compared to that within conventional semiconductors. Fujitsu led the industry with its development of HEMT technology in 1980, and the technology now underpins much of today's fundamental IT infrastructure, including satellite transceivers, wireless equipment, GPS-based navigation systems, and broadband wireless networking systems.
3 Insulated gate:
A gate design that is extremely difficult for current to pass through. Silicon nitride or silicon oxide is typically used as the insulating film.
4 Interface trap level :
A potential arising from the contact between an insulator and semiconductor, or metal and semiconductor. Complicates current control by capturing and emitting electrons.
5 Distortion-compensation circuit:
Applies an inverted distortion at the source to a distorted signal, using a technique known as digital pre-distortion (DPD).
6 Outpower leakage into adjacent channel leakage power:
When a signal is applied, output power will leak into adjacent channels, causing interference and impeding communications.
 

Rahul Singh

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Without a doubt we are on to it. AEW&C is first step and will adequate capability to write modes etc. But LRDE, what don't have is time. They will have to complete half testing of the LCA MK-2 AESA by 2014 and foreign help seems only viable option. I think, fully indigenous AESA should be the target for AMCA Mk-1.
 

nitesh

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Without a doubt we are on to it. AEW&C is first step and will adequate capability to write modes etc. But LRDE, what don't have is time. They will have to complete half testing of the LCA MK-2 AESA by 2014 and foreign help seems only viable option. I think, fully indigenous AESA should be the target for AMCA Mk-1.
Rahul, any idea of production capacity? Correct me if I am wrong but these technologies are given to Astra microwave for serial production. Or some other company is involved in there manufacture.
 

Armand2REP

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India doesn't even have a production PESA MMR and you guys are talking about AESA. That is typical for DRDO to do. Try to run before it can walk, in the end it falls on its face.
 

nitesh

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India doesn't even have a production PESA MMR and you guys are talking about AESA. That is typical for DRDO to do. Try to run before it can walk, in the end it falls on its face.
Armand, the MMR did worked, the problem was with A2G mode. hence the Israelis roped in. AEW program of DRDO is not new, which needs AESA, it was interrupted after the tragic accident in 1999 when the whole team died in a crash. So, you need to wait and see how it progresses
 

nitesh

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What accident was that?
The airframe was not able to take load of the rodome mounted, it fell taking down the plane with it, all scientists involved in the project along with crew died.
A tragic incident.
 

SATISH

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India doesn't even have a production PESA MMR and you guys are talking about AESA. That is typical for DRDO to do. Try to run before it can walk, in the end it falls on its face.
http://en.wikipedia.org/wiki/Airborne_Surveillance_Platform

This was the programme that crashed. It was called Airavat. The crash took place in 1999. It was because of engine failure. It used the HS-748 AVRO. The project was closed after it and with great difficulty was revived in 2004. That led to the modern AEW aircraft with the Embraer platform as it was proven.
 

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