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Exploiting Agile Waveforms and Sampling for Compressive Sensing Radar
Navy SBIR FY2011.2
| Sol No.: |
Navy SBIR FY2011.2 |
| Topic No.: |
N112-161 |
| Topic Title: |
Exploiting Agile Waveforms and Sampling for Compressive Sensing Radar |
| Proposal No.: |
N112-161-0091 |
| Firm: |
C & P Technologies, Inc.
317 Harrington Avenue
Suites 9 & 10
Closter, New Jersey 07624-1911 |
| Contact: |
Ke Li |
| Phone: |
(201) 768-4448 |
| Web Site: |
www.cptnj.com |
| Abstract: |
The goal of the present proposal is to identify and demonstrate enhanced, efficient radar imaging and applications exploiting modern waveform generation. In addition, MIMO beam formation for robust compressive sensing in Maritime applications such as small craft detection and imaging is also proposed. Compressive Sensing has emerged in recent years as a potentially feasible mathematical tool and framework for efficient data collection. However, few active air-to-surface surveillance systems currently exploit the full potential of compressive sensing by probing the ground with fully randomized or partially randomized waveforms. While complete randomization may be impractical, modern digital radar systems are capable of synthesizing a wide variety of modulated waveforms, enabling a more complete and efficient exploration of the time-frequency-angle space over the radar system's path than has been feasible with current methods. Similarly, MIMO radar systems could introduce randomized beam patterns that introduce variations in the angular distribution of signal over targets in each range bin. Finally, an additional layer of randomization and efficient data reduction may be achieved digitally on board the aircraft by weighting and combining pulses over the aperture path before downlink. In this context sparsity based agile waveform design methods are discussed.
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| Benefits: |
Various civil and military systems that depend upon electromagnetic sensing can benefit from the proposed method. Efficient all-weather persistent imaging that is robust to interference will significantly enhance the capability of the warfighter to execute actions and gather intelligence in all environments. Efficient and flexible data transfer utilization can free spectrum for alternate uses. Satellite imaging capabilities can be significantly enhanced. Resource reductions could lead to cost reductions, enabling more widespread use of RF imaging and sensing. Any radar system utilizing a random or less predictable pattern of emissions will likely challenge exploitation opportunities. Alternatively, it is conceivable that many of the compressive sensing and imaging techniques developed here could also be used to enhance minimally invasive medical imaging, exposing patients to less radiation. |
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