Presentation is loading. Please wait.

Presentation is loading. Please wait.

Compressed Sensing in MIMO Radar Chun-Yang Chen and P. P. Vaidyanathan California Institute of Technology Electrical Engineering/DSP Lab Asilomar 2008.

Published byMary Lynette Sparks Modified over 9 years ago

Similar presentations

Presentation on theme: "Compressed Sensing in MIMO Radar Chun-Yang Chen and P. P. Vaidyanathan California Institute of Technology Electrical Engineering/DSP Lab Asilomar 2008."— Presentation transcript:

1 Compressed Sensing in MIMO Radar Chun-Yang Chen and P. P. Vaidyanathan California Institute of Technology Electrical Engineering/DSP Lab Asilomar 2008

2 Outline  Review of the background –Compressed sensing [Donoho 06, Candes&Tao 06…] Compressed sensing in radar [Herman & Strohmer 08] –MIMO radar [Bliss & Forsythe 03, Robey et al. 04, Fishler et al. 04….]  Compressed sensing in MIMO radar –Compressed sensing receiver –Waveform optimization –Examples  Conclusion 2Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008

3 1 Review of the keywords: Compressed sensing, MIMO Radar 3

4 Brief Review of Compressed Sensing 4Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 Goal: Reconstruct s from y.

5 Brief Review of Compressed Sensing 5Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 Goal: Reconstruct s from y. Incoherence: is small.

6 Brief Review of Compressed Sensing 6Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 Goal: Reconstruct s from y. Incoherence: is small. Sparsity: is small.

7 Sparsity: is small. Brief Review of Compressed Sensing 7Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 Goal: Reconstruct s from y. Incoherence: is small. Given y and , s can be perfectly recovered by sparse approximation methods even when dim(y)<dim(s). Given y and , s can be perfectly recovered by sparse approximation methods even when dim(y)<dim(s).

8 Sparsity: is small. Brief Review of Compressed Sensing 8Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 Goal: Reconstruct s from y. Incoherence: is small. This concept can be applied to sampling and compression. Given y and , s can be perfectly recovered by sparse approximation methods even when dim(y)<dim(s). Given y and , s can be perfectly recovered by sparse approximation methods even when dim(y)<dim(s).

9 Review: Compressed Sensing in Radar 9Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 [Herman & Strohmer08] u y targets Range Doppler

10 Review: Compressed Sensing in Radar 10Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 [Herman & Strohmer08] u y targets Range Doppler s i : target RCS in the i-th Range-Doppler cell. * * * *

11 Review: Compressed Sensing in Radar 11Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 [Herman & Strohmer08] u y targets Range Doppler s i : target RCS in the i-th Range-Doppler cell.  is a function of the transmitted waveform u. * * * *

12 * * * * Review: Compressed Sensing in Radar 12Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 [Herman & Strohmer08] u y targets Range Doppler s i : target RCS in the i-th Range-Doppler cell. Assumption: s is sparse. Transmitted waveform u can be chosen such that  is incoherent.  is a function of the transmitted waveform u.

13 Review: Compressed Sensing in Radar 13Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 s i : target RCS in the i-th Range-Doppler cell. Assumption: s is sparse. Transmitted waveform u can be chosen such that  is incoherent. Target scene s can be reconstructed by compressed sensing method. High resolution can be achieved. [Herman & Strohmer08]  is a function of the transmitted waveform u. * * * *

14 Brief Review of MIMO Radar u   u   u   w 2 u  w 1 u  w 0 u   Advantages –Better spatial resolution [Bliss & Forsythe 03] –Flexible transmit beampattern design [Fuhrmann & San Antonio 04] –Improved parameter identifiability [Li et al. 07] Phased array radar (Traditional) Each element transmits a scaled version of a single waveform. Phased array radar (Traditional) Each element transmits a scaled version of a single waveform. MIMO Radar Each element can transmit an arbitrary waveform. MIMO Radar Each element can transmit an arbitrary waveform. Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008

15 2 Compressed Sensing in MIMO Radar 15

16 MIMO Radar Signal Model 16Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 … u 0 (t)u 1 (t)u M-1 (t) (p,,fD)(p,,fD)  delay f D  Doppler p  direction

17 MIMO Radar Signal Model 17Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 … u 0 (t)u 1 (t)u M-1 (t) (p,,fD)(p,,fD) … y 0 (t)y 1 (t)y N-1 (t) (p,,fD)(p,,fD)  delay f D  Doppler p  direction

18 MIMO Radar Signal Model 18Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 … u 0 (t)u 1 (t)u M-1 (t) (p,,fD)(p,,fD) … y 0 (t)y 1 (t)y N-1 (t) (p,,fD)(p,,fD)  delay f D  Doppler p  direction Received signals

19 MIMO Radar Signal Model 19Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 … u 0 (t)u 1 (t)u M-1 (t) (p,,fD)(p,,fD) … y 0 (t)y 1 (t)y N-1 (t) (p,,fD)(p,,fD)  delay f D  Doppler p  direction Range

20 MIMO Radar Signal Model 20Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 … u 0 (t)u 1 (t)u M-1 (t) (p,,fD)(p,,fD) … y 0 (t)y 1 (t)y N-1 (t) (p,,fD)(p,,fD)  delay f D  Doppler p  direction x m : location of the m-th transmitter y n : location of the n-th transmitter Cross range

21 MIMO Radar Signal Model 21Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 … u 0 (t)u 1 (t)u M-1 (t) (p,,fD)(p,,fD) … y 0 (t)y 1 (t)y N-1 (t) (p,,fD)(p,,fD)  delay f D  Doppler p  direction x m : location of the m-th transmitter y n : location of the n-th transmitter for linear array

22 MIMO Radar Signal Model 22Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 … u 0 (t)u 1 (t)u M-1 (t) (p,,fD)(p,,fD) … y 0 (t)y 1 (t)y N-1 (t) (p,,fD)(p,,fD)  delay f D  Doppler p  direction x m : location of the m-th transmitter y n : location of the n-th transmitter Doppler

23 MIMO Radar Signal Model 23Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 Discrete Model:

24 MIMO Radar Signal Model 24Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 Discrete Model: Range Range Cell:L: Length of u m

25 MIMO Radar Signal Model 25Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 Discrete Model: Doppler Range Cell:L: Length of u m Doppler Cell:

26 MIMO Radar Signal Model 26Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 Range Cell:L: Length of u m M: # of transmitting antennas N: # of receiving antennas Doppler Cell: Angle Cell: Discrete Model: Angle

27 MIMO Radar Signal Model 27Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008

28 MIMO Radar Signal Model 28Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 Overall Input-output relation: Overall Input-output relation:

29 MIMO Radar Signal Model 29Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 Overall Input-output relation: Overall Input-output relation:

30 MIMO Radar Signal Model 30Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 Overall Input-output relation: Overall Input-output relation: Range Cell: Doppler Cell: Angle Cell:

31 Compressed Sensing MIMO Radar Receiver 31Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008

32 Compressed Sensing MIMO Radar Receiver 32Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 Received waveforms

33 Compressed Sensing MIMO Radar Receiver 33Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 Received waveforms Transmitted waveforms

34 Compressed Sensing MIMO Radar Receiver 34Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 Received waveforms Transmitted waveforms Transfer function for the target in the  cell

35 Compressed Sensing MIMO Radar Receiver 35Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 Received waveforms Transmitted waveforms Transfer function for the target in the  cell RCS of the target in  cell

36 Compressed Sensing MIMO Radar Receiver 36Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 Received waveforms Transmitted waveforms RCS of the target in  cell Transfer function for the target in the  cell

37 Compressed Sensing MIMO Radar Receiver 37Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 s is sparse if the target scene is sparse.

38 Compressed Sensing MIMO Radar Receiver 38Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 s is sparse if the target scene is sparse. Compressed sensing algorithm can effectively recover s if  is incoherent.

39 Waveform Optimization 39Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 Goal: Design u such that is small. Goal: Design u such that is small.

40 Waveform Optimization 40Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 Goal: Design u such that is small. Goal: Design u such that is small. … … TX RX

41 Waveform Optimization 41Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 Goal: Design u such that is small. Goal: Design u such that is small. … … Small Correlation TX RX

42 Waveform Optimization: Dimension Reduction 42Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008

43 Waveform Optimization: Dimension Reduction 43Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008

44 Waveform Optimization: Dimension Reduction 44Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008

45 Waveform Optimization: Dimension Reduction 45Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008

46 Goal: Design u such that is small. Goal: Design u such that is small. Waveform Optimization: Dimension Reduction 46Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008

47 Waveform Optimization: Beamforming 47Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 B: the set consisting of angles of interest.  To concentrate the transmit energy on the angles of interest, we want the following term to be small

48 Waveform Optimization: Beamforming 48Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008  To uniformly illuminate the angles of interest, we want the following term to be small  To concentrate the transmit energy on the angles of interest, we want the following term to be small B: the set consisting of angles of interest.

49 Waveform Optimization: Cost function 49Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 Incoherent Stopband Passband

50 Waveform Optimization: Cost function 50Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 + +

51 Waveform Optimization: Cost function 51Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 IncoherentStopband Passband

52 Phase Hopping Waveform 52Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 Consider constant-modulus signal:

53 Phase Hopping Waveform 53Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 Consider constant-modulus signal: Consider phase on a lattice:

54 Phase Hopping Waveform 54Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 Consider constant-modulus signal: Consider phase on a lattice:

55 Simulated Annealing Algorithm  Simulated annealing –Create a Markov chain on the set A with the equilibrium distribution –Run the Markov chain Monte Carlo (MCMC) –Decrease the temperature T from time to time 55 subject to … C C’ … Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008

56 Example: Histogram of correlations 56Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 Parameters: Uniform linear array # of RX elements N=10 # of TX elements M =4 Signal length L=31 # of phase K=15 Angle of interest ALL # of (  ’) pairs Alltop Sequence Proposed Method

57 Example: Histogram of correlations 57Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 # of (  ’) pairs Alltop Sequence Proposed Method Parameters: Uniform linear array # of RX elements N=10 # of TX elements M =4 Signal length L=31 # of phase K=15 Angle of interest ALL

58 Example: Histogram of correlations 58Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 # of (  ’) pairs Alltop Sequence Proposed Method Parameters: Uniform linear array # of RX elements N=10 # of TX elements M =4 Signal length L=31 # of phase K=15 Angle of interest ALL

59 Example: Recovering Target Scene 59Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 Target Scene Compressed Sensing Matched Filter SNR=10dB

60 Example: Recovering Target Scene 60Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 Target Scene Compressed Sensing Matched Filter SNR=10dB

61 Example: Recovering Target Scene 61Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 Target Scene Compressed Sensing Matched Filter SNR=10dB

62 Example: Recovering Target Scene 62Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008 Target Scene Compressed Sensing Matched Filter SNR=10dB

63 Conclusion  Compressed sensing based receiver –Applicable when the target scene is sparse –Better resolution than the matched filter receiver  Waveform design –Incoherent –Beamforming –Simulated annealing 63Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008

64 Q&A Thank You! Any questions? 64Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008

65 Simulated Annealing Algorithm  Simulated annealing –Create a Markov chain on the set A with the equilibrium distribution 65 subject to … C C’ … Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008

66 Simulated Annealing Algorithm  Simulated annealing –Create a Markov chain on the set A with the equilibrium distribution –Run the Markov chain Monte Carlo (MCMC) 66 subject to … C C’ … Chun-Yang Chen, Caltech DSP Lab | Asilomar 2008

Download ppt "Compressed Sensing in MIMO Radar Chun-Yang Chen and P. P. Vaidyanathan California Institute of Technology Electrical Engineering/DSP Lab Asilomar 2008."

Similar presentations

Bayesian Belief Propagation

Bayesian Belief Propagation
A Subspace Method for MIMO Radar Space-Time Adaptive Processing

A Subspace Method for MIMO Radar Space-Time Adaptive Processing
Compressive Data Gathering for Large-Scale Wireless Sensor Networks

Compressive Data Gathering for Large-Scale Wireless Sensor Networks
An Adaptive Learning Method for Target Tracking across Multiple Cameras Kuan-Wen Chen, Chih-Chuan Lai, Yi-Ping Hung, Chu-Song Chen National Taiwan University.

An Adaptive Learning Method for Target Tracking across Multiple Cameras Kuan-Wen Chen, Chih-Chuan Lai, Yi-Ping Hung, Chu-Song Chen National Taiwan University.
Design Rule Generation for Interconnect Matching Andrew B. Kahng and Rasit Onur Topaloglu {abk | rtopalog University of California, San Diego.

Design Rule Generation for Interconnect Matching Andrew B. Kahng and Rasit Onur Topaloglu {abk | rtopalog University of California, San Diego.
Beamforming Issues in Modern MIMO Radars with Doppler

Beamforming Issues in Modern MIMO Radars with Doppler
Minimum Redundancy MIMO Radar Chun-Yang Chen and P. P. Vaidyanathan California Institute of Technology Electrical Engineering/DSP Lab ISCAS 2008.

Minimum Redundancy MIMO Radar Chun-Yang Chen and P. P. Vaidyanathan California Institute of Technology Electrical Engineering/DSP Lab ISCAS 2008.
Antarctic Ice Shelf 3D Cross-sectional Imaging using MIMO Radar A. Hari Narayanan UCL Electronic and Electrical Engineering, UK P. Brennan UCL Electronic.

Antarctic Ice Shelf 3D Cross-sectional Imaging using MIMO Radar A. Hari Narayanan UCL Electronic and Electrical Engineering, UK P. Brennan UCL Electronic.
Comparison of different MIMO-OFDM signal detectors for LTE

Comparison of different MIMO-OFDM signal detectors for LTE
Multi-Task Compressive Sensing with Dirichlet Process Priors Yuting Qi 1, Dehong Liu 1, David Dunson 2, and Lawrence Carin 1 1 Department of Electrical.

Multi-Task Compressive Sensing with Dirichlet Process Priors Yuting Qi 1, Dehong Liu 1, David Dunson 2, and Lawrence Carin 1 1 Department of Electrical.
Contents 1. Introduction 2. UWB Signal processing 3. Compressed Sensing Theory 3.1 Sparse representation of signals 3.2 AIC (analog to information converter)

Contents 1. Introduction 2. UWB Signal processing 3. Compressed Sensing Theory 3.1 Sparse representation of signals 3.2 AIC (analog to information converter)
Folie 1 Ambiguity Suppression by Azimuth Phase Coding in Multichannel SAR Systems DLR - Institut für Hochfrequenztechnik und Radarsysteme F. Bordoni, M.

Folie 1 Ambiguity Suppression by Azimuth Phase Coding in Multichannel SAR Systems DLR - Institut für Hochfrequenztechnik und Radarsysteme F. Bordoni, M.
Folie 1 Performance Investigation on the High-Resolution Wide-Swath SAR System Operating in Stripmap Quad-Pol and Ultra-Wide ScanSAR Mode DLR - Institut.

Folie 1 Performance Investigation on the High-Resolution Wide-Swath SAR System Operating in Stripmap Quad-Pol and Ultra-Wide ScanSAR Mode DLR - Institut.
Joint MIMO Radar Waveform and Receiving Filter Optimization Chun-Yang Chen and P. P. Vaidyanathan California Institute of Technology Electrical Engineering/DSP.

Joint MIMO Radar Waveform and Receiving Filter Optimization Chun-Yang Chen and P. P. Vaidyanathan California Institute of Technology Electrical Engineering/DSP.
Volkan Cevher, Marco F. Duarte, and Richard G. Baraniuk European Signal Processing Conference 2008.

Volkan Cevher, Marco F. Duarte, and Richard G. Baraniuk European Signal Processing Conference 2008.
Compressive Data Gathering for Large- Scale Wireless Sensor Networks Chong Luo Feng Wu Shanghai Jiao Tong University Microsoft Research Asia Jun Sun Chang.

Compressive Data Gathering for Large- Scale Wireless Sensor Networks Chong Luo Feng Wu Shanghai Jiao Tong University Microsoft Research Asia Jun Sun Chang.
Properties of the MIMO Radar Ambiguity Function

Properties of the MIMO Radar Ambiguity Function
Coherent MIMO Radar: High Resolution Applications

Coherent MIMO Radar: High Resolution Applications
DSP Group, EE, Caltech, Pasadena CA1 Precoded V-BLAST for ISI MIMO Channels Chun-yang Chen and P. P. Vaidyanathan California Institute of Technology.

DSP Group, EE, Caltech, Pasadena CA1 Precoded V-BLAST for ISI MIMO Channels Chun-yang Chen and P. P. Vaidyanathan California Institute of Technology.
A Design Method for MIMO Radar Frequency Hopping Codes Chun-Yang Chen and P. P. Vaidyanathan California Institute of Technology Electrical Engineering/DSP.

A Design Method for MIMO Radar Frequency Hopping Codes Chun-Yang Chen and P. P. Vaidyanathan California Institute of Technology Electrical Engineering/DSP.

Similar presentations

Ads by Google