Читать книгу Inverse Synthetic Aperture Radar Imaging With MATLAB Algorithms - Caner Ozdemir - Страница 2

1  Cover

2  Series Page

3  Title Page

4  Copyright Page

5  Dedication Page

6  Preface to the Second Edition

7  Acknowledgments

8  Acronyms

9  1 Basics of Fourier Analysis 1.1 Forward and Inverse Fourier Transform 1.2 FT Rules and Pairs 1.3 Time‐Frequency Representation of a Signal 1.4 Convolution and Multiplication Using FT 1.5 Filtering/Windowing 1.6 Data Sampling 1.7 DFT and FFT 1.8 Aliasing 1.9 Importance of FT in Radar Imaging 1.10 Effect of Aliasing in Radar Imaging 1.11 Matlab Codes References

10  2 Radar Fundamentals 2.1 Electromagnetic Scattering 2.2 Scattering from PECs 2.3 Radar Cross Section 2.4 Radar Range Equation 2.5 Range of Radar Detection 2.6 Radar Waveforms 2.7 Pulsed Radar 2.8 Matlab Codes References

11  3 Synthetic Aperture Radar 3.1 SAR Modes 3.2 SAR System Design 3.3 Resolutions in SAR 3.4 SAR Image Formation 3.5 Range Compression 3.6 Azimuth Compression 3.7 SAR Imaging 3.8 SAR Focusing Algorithms 3.9 Example of a Real SAR Imagery 3.10 Problems in SAR Imaging 3.11 Advanced Topics in SAR 3.12 Matlab Codes References

12  4 Inverse Synthetic Aperture Radar Imaging and Its Basic Concepts 4.1 SAR versus ISAR 4.2 The Relation of Scattered Field to the Image Function in ISAR 4.3 One‐Dimensional (1D) Range Profile 4.4 1D Cross‐Range Profile 4.5 Two‐Dimensional (2D) ISAR Image Formation (Small Bandwidth, Small Angle) 4.6 2D ISAR Image Formation (Wide Bandwidth, Large Angles) 4.7 3D ISAR Image Formation 4.8 Matlab Codes References

13  5 Imaging Issues in Inverse Synthetic Aperture Radar 5.1 Fourier‐Related Issues 5.2 Image Aliasing 5.3 Polar Reformatting Revisited 5.4 Zero Padding 5.5 Point Spread Function 5.6 Windowing 5.7 Matlab Codes References

14  6 Range‐Doppler Inverse Synthetic Aperture Radar Processing 6.1 Scenarios for ISAR 6.2 ISAR Waveforms for Range‐Doppler Processing 6.3 Doppler Shift's Relation to Cross‐Range 6.4 Forming the Range‐Doppler Image 6.5 ISAR Receiver 6.6 Quadrature Detection 6.7 Range Alignment 6.8 Defining the Range‐Doppler ISAR Imaging Parameters 6.9 Example of Chirp Pulse‐Based Range‐Doppler ISAR Imaging 6.10 Example of SFCW‐Based Range‐Doppler ISAR Imaging 6.11 Matlab Codes References

15  7 Scattering Center Representation of Inverse Synthetic Aperture Radar 7.1 Scattering/Radiation Center Model 7.2 Extraction of Scattering Centers 7.3 Matlab Codes References

16  8 Motion Compensation for Inverse Synthetic Aperture Radar 8.1 Doppler Effect Due to Target Motion 8.2 Standard MOCOMP Procedures 8.3 Popular ISAR MOCOMP Techniques 8.4 Matlab Codes References

17  9 Bistatic ISAR Imaging 9.1 Why Bi‐ISAR Imaging? 9.2 Geometry for Bi‐Isar Imaging and the Algorithm 9.3 Resolutions in Bistatic ISAR 9.4 Design Procedure for Bi‐ISAR Imaging 9.5 Bi‐Isar Imaging Examples 9.6 Mu‐ISAR Imaging 9.7 Matlab Codes References

18  10 Polarimetric ISAR Imaging 10.1 Polarization of an Electromagnetic Wave 10.2 Polarization Scattering Matrix 10.3 Why Polarimetric ISAR Imaging? 10.4 ISAR Imaging with Full Polarization 10.5 Polarimetric ISAR Images 10.6 Feature Extraction from Polarimetric Images 10.7 Matlab Codes References

19  11 Near‐Field ISAR Imaging 11.1 Definitions of Far and Near‐Field Regions 11.2 Near‐Field Signal Model for the Back‐Scattered Field 11.3 Near‐Field ISAR Imaging Algorithms 11.4 Data Sampling Criteria and the Resolutions 11.5 Near‐Field ISAR Imaging Examples 11.6 Matlab Codes References

20  12 Some Imaging Applications Based on SAR/ISAR 12.1 Imaging Subsurface Objects: GPR‐SAR 12.2 Thru‐the‐Wall Imaging Radar Using SAR 12.3 Imaging Antenna‐Platform Scattering: ASAR 12.4 Imaging Platform Coupling Between Antennas: ACSAR References

21  Appendix

22  Index

23  Wiley Series in Microwave and Optical Engineering

24  End User License Agreement