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More Than Just A New Radar

SBD-3

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February 3, 2010: AESA (Active Electronically Scanned Array) radars are becoming standard equipment in modern warplanes, for those that can afford them, and appreciate their power and versatility. This is largely because AESA is more reliable and, increasingly, no more expensive than the older mechanical (a small dish that moves around inside a dome) radar. AESA is also easier and cheaper to maintain, which makes a more expensive AESA cheaper, over its lifetime, than a cheaper (to buy) mechanically scanned radar.

AESA type radars have been around a long time, popular mainly for their ability deal with lots of targets simultaneously, and produce a more accurate picture of what is out there. But AESA was also a lot more expensive, and less reliable, than older radar technologies. That has gradually changed. And now more uses are being found for AESA, which has developed into more than just an improved radar.

AESA radar consists of thousands of tiny radars that can be independently aimed in different directions. An AESA radar made the JSTARS aircraft possible, as it enabled it to locate vehicles moving on the ground. A new, smaller MP-RTIP AESA radar for the RQ-4 UAV can also spot smaller objects on the ground. As a result, with the RQ-4 UAV equipped with AESA, the U.S. Air Force has a choice between extending the life of the E-8 aircraft, or replacing them with the UAVs.

While AESA makes fighters much more effective, it's the many other uses of AESA that make this technology so attractive to warplane designers. For example, the U.S. Air Force has been equipping some of its fighters with electronic ray type weapons. Not quite the “death ray” of science fiction fame, but an electronic ray type weapon none the less. In this case, the weapon uses the high-powered microwave (HPM) effects found in AESA radar technology. AESA is able to focus a concentrated beam of radio energy that could scramble electronic components of a distant target. Sort of like the EMP (Electromagnetic Pulse) put out by nuclear weapons. The air force won’t, for obvious reasons, discuss the exact “kill range” of the of the various models of AESA radars on American warplanes (the F-35 and F-22 have them). However, it is known that “range” in this case is an elastic thing. Depending on how well the target electronics are hardened against EMP, more electrical power will be required to do damage. Moreover, the electrical power of the various AESA radars in service varies as well. The air force has said that the larger AESA radars it is developing would be able to zap cruise missile guidance systems up to 180 kilometers away.
 
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Heat generated by AESA radar in a closed environment such as Radome of a small aircraft (Jf-17) must cause a major problem. Any ideas how it is resolved?
 
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Heat generated by AESA radar in a closed environment such as Radome of a small aircraft (Jf-17) must cause a major problem. Any ideas how it is resolved?

S A Brothers (sabro) must have a solution for this, but they would need cash and in advance to keep their balance sheet low as usual to avoid tax at maximum :azn:
 
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Heat generated by AESA radar in a closed environment such as Radome of a small aircraft (Jf-17) must cause a major problem. Any ideas how it is resolved?

I guess air cooling is the standard way for cooling. Those side vents are there for this specific purpose.
 
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AESA will dissipate a lot of heat which must be extracted to prevent the transmitter chips becoming molten pools of Gallium Arsenide - reliability of GaAs MMIC chips improves the cooler they are run. Traditional air cooling used in most established avionic hardware is ill suited to the high packaging density of an AESA, as a result of which modern AESAs are liquid cooled. US designs employ a polyalphaolefin (PAO) coolant similar to a synthetic hydraulic fluid. A typical liquid cooling system will use pumps to drive the coolant through channels in the antenna, and then route it to a heat exchanger. That might be an air cooled core (radiator style) or an immersed heat exchanger in a fuel tank - with a second liquid cooling loop to dump heat from the fuel tank. In comparison with a conventional air cooled fighter radar, the AESA will be more reliable but will require more electrical power and more cooling, and typically can produce much higher transmit power if needed for greater target detection range performance (increasing transmitted power has the drawback of increasing the footprint over which a hostile ESM or RWR can detect the radar.

Regards
 
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I guess air cooling is the standard way for cooling. Those side vents are there for this specific purpose.

there are millions of heatsink designs used in electric equipments, but in aircrafts airflow is safe and obvious
 
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