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Simultaneous
Range-Doppler Radar (SRD) raises the standard for information
extracted from radar returns. With SRD Radar, the end user
receives
big-system high-performance capability in smaller, more mobile
platforms, enhancing air superiority and air-space dominance, while
leaving no sanctuary for our adversaries
Frequently Asked Questions
- Will SRD technology allow radars to operate with
reduced transmit
power? If so, how?
- Will SRD technology allow radars to see smaller
targets at longer
ranges? If so, how?
- Will SRD technology allow radars to improve their
performance against
targets embedded in surface and volumetric (weather) clutter? If so,
how?
- Will SRD technology
allow radars to reduce their false alarm rates?
If so, how?
- Will SRD technology
improve radars ability to counter RF
interference and jamming? If so, how?
- Will SRD technology
improve radars ability to estimate target
parameters such as azimuth, elevation, velocity, range, etc.? If so,
how?
- How will SRD technology
reduce the cost of our radars systems?
- Can SRD technology be
retrofitted into our current radars or does it
apply to new designs only?
- If SRD
technology can be retrofitted into existing radars, what
changes must be made to existing architectures, hardware, software,
waveforms,
signal processing, detection processing, data processing, target
tracking,
etc.?
- Is SRD technology
applicable to all radar modes or does it apply
only to a special mode?
- Does SRD technology apply to reflector as well as
phased array
radars?
- How much further
development is required before SRD technology can
be inserted into existing radars?
- How can SRD technology operate with longer
pulses? How does SRD technology overcome Doppler Fragility?
- How can SRD technology achieve, with a
single pulse, the detection performance of Coherent Pulse Integration?
- How does SRD technology achieve a computational
advantage over current state of the art?
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