A Neural Network Approach for Waveform Generation and Selection with Multi-Mission Radar

Nonlinear frequency modulated (NLFM) pulse compression waveforms have become a mainstream methodology for radars across multiple sectors and missions, including weather observation, target tracking, and target detection. NLFM affords the ability to generate a low-sidelobe autocorrelation function and matched filter while avoiding aggressive amplitude modulation, resulting in more power incident on the target. This capability can lead to significantly lower system design costs due to the possibility of sensitivity gains on the order of 3 dB or more compared with traditional, amplitude-modulated linear frequency modulated (LFM) waveforms. Generation of an optimal NLFM waveform, however, can be an arduous task, and may involve complex optimization and non-closed-form solutions. For a multi-mission or cognitive radar, which may utilize a wide combination of frequencies, pulse lengths, and amplitude modulations (among other factors), this could lead to an extremely large waveform table for selection. This paper takes a neural network approach to this problem by optimizing a set of over 100 waveforms spanning a wide space and using the results to interpolate the waveform possibilities to a higher resolution. A modified form of a previous NLFM method is combined with a four-hidden-layer neural network to show the integrated and peak range sidelobes of the generated waveforms across the model training space. The results are applicable to multi-mission and cognitive radars that need precise waveform specifications in rapid succession. The expected waveform generation times are addressed and quantified, and the potential applicability to multi-mission and cognitive radars is discussed.

[1]  Joan Bech,et al.  Improving weather radar observations using pulse‐compression techniques , 2007 .

[2]  Sebastián M. Torres,et al.  Requirement-Driven Design of Pulse Compression Waveforms for Weather Radars , 2017 .

[3]  John Y. N. Cho,et al.  The Next-Generation Multimission U.S. Surveillance Radar Network , 2007 .

[4]  V. Chandrasekar,et al.  Sensitivity Enhancement System for Pulse Compression Weather Radar , 2011 .

[5]  Hugh Griffiths,et al.  Improved ultra-low range sidelobe pulse compression waveform design , 2004 .

[6]  Yan Zhang,et al.  The Atmospheric Imaging Radar: Simultaneous Volumetric Observations Using a Phased Array Weather Radar , 2013 .

[7]  S. Haykin,et al.  Cognitive radar: a way of the future , 2006, IEEE Signal Processing Magazine.

[8]  Andrew D. Byrd,et al.  Observations of Severe Local Storms and Tornadoes with the Atmospheric Imaging Radar , 2015 .

[9]  Mark B. Yeary,et al.  PX-1000: A Solid-State Polarimetric X-Band Weather Radar and Time–Frequency Multiplexed Waveform for Blind Range Mitigation , 2013, IEEE Transactions on Instrumentation and Measurement.

[10]  S. Haykin,et al.  Optimal waveform design for cognitive radar , 2008, 2008 42nd Asilomar Conference on Signals, Systems and Computers.

[11]  Nitin Bharadwaj,et al.  Wideband Waveform Design Principles for Solid-State Weather Radars , 2012 .

[12]  R. Vogt,et al.  Agile-Beam Phased Array Radar for Weather Observations , 2007 .

[13]  R. J. Keeler,et al.  Pulse compression for weather radar , 1995, Proceedings International Radar Conference.

[14]  Robert D. Palmer,et al.  A Pulse Compression Waveform for Improved-Sensitivity Weather Radar Observations , 2014 .

[15]  Travis M. Smith,et al.  Rapid Sampling of Severe Storms by the National Weather Radar Testbed Phased Array Radar , 2008 .

[16]  V. Chandrasekar,et al.  Pulse compression for weather radars , 1998, IEEE Trans. Geosci. Remote. Sens..

[17]  Hugh Griffiths,et al.  Design of low-sidelobe pulse compression waveforms , 1994 .