Principles of Modern Radar - Volume 2 1891121537

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5.8 References 205[152] Rigling, B.D. and Moses, R.L., “GTD-Based Scattering Models for Bistatic SAR,”pp. 208–219 in Algorithms for Synthetic Aperture Radar Imagery XI, vol. 5427, Ed. E.G.Zelnio, SPIE, 2004.[153] Jackson, J., Rigling, B., and Moses, R., “Canonical Scattering Feature Models for 3-D andBistatic SAR,” IEEE Transactions on Aerospace and Electronic Systems, vol. 46, no. 2,pp. 525–541, 2010.[154] Jackson, J.A. and Moses, R.L., “An Algorithm for 3-D Target Scatterer Feature Estimationfrom Sparse SAR Apertures,” in Algorithms for Synthetic Aperture Radar Imagery XVI,vol. 7337, Ed. E.G. Zelnio and F.D. Garber, Proceedings of SPIE, 2009.[155] Greengard, L. and Lee, J.Y., “Accelerating the Nonuniform Fast Fourier Transform,” SIAMReview, vol. 46, pp. 443–454, 2004.[156] Beylkin, G., Gorman, J., Li-Fliss, S., and Ricoy, M., “SAR Imaging and MultiresolutionAnalysis,” pp. 2144–2152 in Proceedings of the SPIE: Algorithms for Synthetic ApertureRadar Imagery II, vol. 2487, Ed. D.A. Giglio, pp. 2144–152, SPIE, 1995.[157] Andersson, F., Moses, R., and Natterer, F., “Fast Fourier Methods for Synthetic ApertureRadar Imaging,” IEEE Transactions on Aerospace and Electronic Systems, vol. 48,January 2012.[158] Demanet, L., Ferrara, M., Maxwell, N., Poulson, J., and Ying, L., “A Buttery Algorithm forSynthetic Aperture Radar Imaging,” Submitted to SIAM Imaging Sciences, September 2010.[159] Delaney, A. and Bresler, Y., “A Fast and Accurate Fourier Algorithm for Iterative Parallel-Beam Tomography,” IEEE Transactions on Image Processing, vol. 5, pp. 740–753, May 1996.[160] Curtis, J., Casteel, H., Gorham, L.A., Minardi, M.J., Scarborough, S.M., Naidu, K.D., andMajumder, U.K., “A Challenge Problem for 2-D/3-D Imaging of Targets from a VolumetricData Set in an Urban Environment,” P. 65680D in Proceedings of SPIE, vol. 6568, Ed. E.G.Zelnio and F.D. Garber, SPIE, 2007.[161] Wahl, D.E., Eichel, P.H., Ghiglia, D.C., Thompson, P.A., and Jakowatz, C.V., Spotlight-ModeSynthetic Aperture Radar: A Signal Processing Approach, Springer, 1996.[162] Soumekh, M., Synthetic Aperture Radar Signal Processing with MATLAB Algorithms,John Wiley & Sons, Interscience Division, New York, 1999.[163] Moses, R.L. and Potter, L.C., “Noncoherent 2-D and 3-D SAR Reconstruction fromWide-Angle Measurements,” in 13th Annual Adaptive Sensor Array Processing Workshop,MIT Lincoln Laboratory, 2005.[164] Austin, C.D., Ertin, E., and Moses, R.L., “Sparse Multipass 3-D SAR Imaging: Applicationsto the GOTCHA Data Sets,” in Algorithms for Synthetic Aperture Radar Imagery XVI,Ed. E.G. Zelnio and F.D. Garber, Orlando, FL, SPIE Defense and Security Symposium,April 13–17, 2009.[165] Stojanovic, I. and Karl, W., “Imaging of Moving Targets with Multi-static SAR Using anOvercomplete Dictionary,” IEEE Journal of Selected Topics in Signal Processing, vol. 4,no. 1, pp. 164–176, 2010.[166] Rossi, D.J. and Willsky, A.S., “Reconstruction from Projections Based on Detection andEstimation of Objects—Part I: Performance Analysis and Part II: Robustness Analysis,”IEEE Transactions on Acoustics, Speech and Signal Processing, vol. 32, pp. 886–906,August 1984.[167] Ertin, E., Potter, L., and Moses, R., “Enhanced Imaging over Complete Circular Apertures,”in 40th Asilomar Conference on Signals, Systems and Computers, pp. 1580–1584,October 29–November 1, 2006.
206 CHAPTER 5 Radar Applications of Sparse Reconstruction[168] Voccola, K., Yazici, B., Ferrara, M., and Cheney, M., “On the Relationship betweenthe Generalized Likelihood Ratio Test and Backprojection for Synthetic ApertureRadar Imaging,” in Automatic Target Recognition XIX, vol. 7335, Ed. F.A. Sadjadi andA. Mahalanobis, Proceedings of the SPIE, 2009.[169] Deming, R.W. and Devaney, A.J., “Diffraction Tomography for Multi-monostatic GroundPenetrating Radar Imaging,” Inverse Problems, vol. 13, no. 1, p. 29, 1997.[170] P. Meincke, “Linear GPR Inversion for Lossy Soil and a Planar Air-Soil Interface,” IEEETransactions on Geoscience and Remote Sensing, vol. 39, pp. 2713–2721, December 2001.[171] Cui, T.J. and Chew, W.J., “Diffraction Tomographic Algorithm for the Detection ofThree-Dimensional Objects Buried in a Lossy Half-Space,” IEEE Transactions on Antennasand Propagation, vol. 50, no. 1, pp. 42–49, 2002.[172] Zhadanov, M.S., Geophysical Inverse Theory and Regularization Problems, ElsevierScience Inc., 2002.[173] Lo Monte, L., Erricolo, D., Soldovieri, F., and Wicks, M.C., “Radio Frequency Tomographyfor Tunnel Detection,” IEEE Transactions on Geoscience and Remote Sensing, vol. 48,pp. 1128–1137, March 2010.[174] Lo Monte, L. and Parker, J., “Sparse Reconstruction Methods in RF Tomography forUnderground Imaging,” in International Waveform Design and Diversity Conference, 2010.[175] Giannopoulos, A., “GPRMAX Simulator.” Available at http://www.gprmax.org.[176] Hansen, P.C., “The L-Curve and Its Use in the Numerical Treatment of Inverse Problems,”in Computational Inverse Problems in Electrocardiology, Ed. P. Johnston, pp. 119–142,WIT Press, Southampton, 2001.[177] Golub, G.H. and von Matt, U., “Generalized Cross-Validation for Large Scale Problems,”J. Comput. Graph. Stat, vol. 6, pp. 1–34, 1995.[178] Scherzer, O., “The Use of Morozov’s Discrepancy Principle for Tikhonov Regularizationfor Solving Nonlinear Ill-Posed Problems,” Computing, vol. 51, pp. 45–60, 1993.10.1007/BF02243828.[179] Efron, B., Hastie, T., Johnstone, I., and Tibshirani, R., “Least Angle Regression,” Annals ofStatistics, vol. 32, no. 2, pp. 407–499, 2004.[180] Cheney, M. and Borden, B., “Problems in Synthetic-Aperture Radar Imaging,” InverseProblems, vol. 25, no. 12, p. 123005, 2009.[181] Colton, D. and Kirsch, A., “A Simple Method for Solving Inverse Scattering Problems inthe Resonance Region,” Inverse Problems, vol. 12, no. 4, p. 383, 1996.[182] Alqadah, H., Parker, J., Ferrara, M., and Fan, H., “A Single Frequency Sparsity-ConstrainedLinear Sampling Method,” in Defense Applications of Signal Processing, 2009.[183] Alqadah, H., Fan, H., Ferrara, M., and Parker, J., “A Modified Total-Variation Approach forSingle-Frequency Inverse Scattering,” in IEEE Asilomar Conference on Signals, Systems,and Computers, 2010.[184] Potthast, R., Point Sources and Multipoles in Inverse Scattering Theory, Chapman andHall/CRC, 2001.[185] Brignone, M., Bozza, G., Aramini, R., Pastorino, M., and Piana, M., “A Fully No-SamplingFormulation of the Linear Sampling Method for Three-Dimensional Inverse ElectromagneticScattering Problems,” Inverse Problems, vol. 25, no. 1, p. 015014, 2009.[186] Colton, D. and Kress, R., Inverse Acoustic and Electromagnetic Scattering Theory, 2d ed.,Springer, 1998.
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Principles of Modern Radar
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Published by SciTech Publishing, an
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Brief ContentsPreface xvPublisher A
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xContents3.6 Adaptive MIMO Radar 10
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xiiContents9.3 Adaptive Jammer Canc
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xivContents15.3 Multisensor Trackin
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xviPrefacehas always been the unlik
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Publisher AcknowledgmentsTechnical
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Editors and ContributorsVolume Edit
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xxiiEditors and ContributorsDr. Lis
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xxivEditors and ContributorsMr. Ara
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2 CHAPTER 1 Overview: Advanced Tech
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1.3 Radar and System Topologies 5FI
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1.4 Topics in Advanced Techniques 7
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1.6 References 15TABLE 1-1Summary o
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PART IWaveforms and SpectrumCHAPTER
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20 CHAPTER 2 Advanced Pulse Compres
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2.2 Stretch Processing 35is applied
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2.2 Stretch Processing 37TABLE 2-1
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2.5 Stepped Frequency Waveforms 61T
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2.5 Stepped Frequency Waveforms 63w
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2.5 Stepped Frequency Waveforms 69I
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2.9 References 812.7.4 SummaryWhile
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2.9 References 83[27] Taylor, Jr.,
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2.10 Problems 85shift across the pu
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88 CHAPTER 3 Optimal and Adaptive M
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3.2 Optimum MIMO Waveform Design fo
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3.4 Optimum MIMO Design for Target
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3.4 Optimum MIMO Design for Target
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3.5 Constrained Optimum MIMO Radar
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108 CHAPTER 3 Optimal and Adaptive
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3.6 Adaptive MIMO Radar 111SINR Los
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3.10 Problems 115[22] W. Y. Hsiang,
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3.10 Problems 1179. A constrained o
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120 CHAPTER 4 MIMO Radarperformance
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4.3 The MIMO Virtual Array 123separ
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4.4 MIMO Radar Signal Processing 12
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134 CHAPTER 4 MIMO RadarFIGURE 4-7T
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136 CHAPTER 4 MIMO Radar4.5.2 MIMO
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138 CHAPTER 4 MIMO Radarnamely, R
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140 CHAPTER 4 MIMO RadarTABLE 4-2 P
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142 CHAPTER 4 MIMO RadarSINR Loss (
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144 CHAPTER 4 MIMO Radar[10] H. V.
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Radar Applications of SparseReconst
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5.1 Introduction 149δ = M/N, the u
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152 CHAPTER 5 Radar Applications of
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Page 188 and 189: 5.2 CS Theory 163While the notion o
Page 190 and 191: 5.2 CS Theory 165as , where is a b
Page 192 and 193: 5.3 SR Algorithms 167than the norm
Page 194 and 195: 5.3 SR Algorithms 169the value of o
Page 196 and 197: 5.3 SR Algorithms 171takes special
Page 198 and 199: 5.3 SR Algorithms 173The function f
Page 200 and 201: 5.3 SR Algorithms 175of the TV norm
Page 202 and 203: 5.3 SR Algorithms 177One can argue
Page 204 and 205: 5.3 SR Algorithms 179probability ma
Page 206 and 207: 5.3 SR Algorithms 181only a subset
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Page 216 and 217: 5.4 Sample Radar Applications 191Ra
Page 218 and 219: 5.4 Sample Radar Applications 193Ta
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Page 236 and 237: Spotlight SyntheticAperture RadarCH
Page 238 and 239: 6.1 Introduction 213• Image quali
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Page 242 and 243: 6.2 Mathematical Background 2172π
Page 245: 220 CHAPTER 6 Spotlight Synthetic A
Page 249 and 250: 224 CHAPTER 6 Spotlight Synthetic A
Page 256 and 257: 6.4 Sampling Requirements and Resol
Page 258 and 259: 6.4 Sampling Requirements and Resol
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Page 264 and 265: 6.5 Image Reconstruction 239FIGURE
Page 266 and 267: 6.6 Image Metrics 241The contrast r
Page 268 and 269: 6.6 Image Metrics 243Along-track am
Page 270: 6.7 Phase Error Effects 245TABLE 6-
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256 CHAPTER 6 Spotlight Synthetic A
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258 CHAPTER 6 Spotlight Synthetic A
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260 CHAPTER 7 Stripmap SAR3 m SAR O
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262 CHAPTER 7 Stripmap SAR• RMA i
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264 CHAPTER 7 Stripmap SARH 0 (ω)
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268 CHAPTER 7 Stripmap SARTABLE 7-1
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274 CHAPTER 7 Stripmap SARFIGURE 7-
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276 CHAPTER 7 Stripmap SAR−500Sce
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7.3 Doppler Beam Sharpening Extensi
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288 CHAPTER 7 Stripmap SARand in th
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7.4 Range-Doppler Algorithms 291to
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7.4 Range-Doppler Algorithms 293For
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296 CHAPTER 7 Stripmap SAR−150Col
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300 CHAPTER 7 Stripmap SAR33 cycles
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302 CHAPTER 7 Stripmap SARCrossrang
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304 CHAPTER 7 Stripmap SARfrom freq
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7.5 Range Migration Algorithm 307r,
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310 CHAPTER 7 Stripmap SARkx (rad/m
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316 CHAPTER 7 Stripmap SARThe diffe
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320 CHAPTER 7 Stripmap SARLet us re
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322 CHAPTER 7 Stripmap SARThe resul
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324 CHAPTER 7 Stripmap SARscene. Th
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326 CHAPTER 7 Stripmap SARdriven by
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328 CHAPTER 7 Stripmap SARTABLE 7-3
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330 CHAPTER 7 Stripmap SARFIGURE 7-
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332 CHAPTER 7 Stripmap SAR7.10 REFE
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334 CHAPTER 7 Stripmap SAR6. [MATLA
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Interferometric SAR andCoherent Exp
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8.1 Introduction 3398.1.1 Organizat
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8.1 Introduction 341Rsabnv rw x ,w
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8.2 Digital Terrain Models 343FIGUR
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8.3 Estimating Elevation Profiles U
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352 CHAPTER 8 Interferometric SAR a
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8.5 InSAR Processing Steps 365ξ ta
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8.5 InSAR Processing Steps 3670.1 0
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8.5 InSAR Processing Steps 373While
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8.6 Error Sources 375The second met
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8.6 Error Sources 377If sufficient
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Adaptive Digital BeamformingCHAPTER
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9.1 Introduction 403c k = clutter s
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408 CHAPTER 9 Adaptive Digital Beam
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9.2 Digital Beamforming Fundamental
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9.3 Adaptive Jammer Cancellation 42
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9.5 Wideband Cancellation 447FIGURE
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454 CHAPTER 10 Clutter Suppression
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10.2 Space-Time Signal Representati
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10.5 STAP Fundamentals 4810−5−1
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10.6 STAP Processing Architectures
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10.7 Other Considerations 4911 CPIM
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10.9 Summary 49310.7.3 Computationa
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10.10 References 495[12] Fenner, D.
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10.11 Problems 497the PSD in Figure
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11.2 Colored Space-Time Exploration
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11.2 Colored Space-Time Exploration
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506 CHAPTER 11 Space-Time Coding fo
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11.8 References 525Cost reduction o
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11.9 Problems 52711.9.2 Equivalence
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530 CHAPTER 12 Electronic Protectio
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12.2 Electronic Attack 535TABLE 12-
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12.2 Electronic Attack 541variation
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12.5 Antenna-Based EP 557are adjust
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12.6 Transmitter-Based EP 561polari
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12.11 Summary 583TABLE 12-4Summary
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12.14 Problems 585[9] Stimson, G.W.
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Introduction to RadarPolarimetryCHA
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13.1 Introduction 591and precipitat
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13.1 Introduction 593S: target scat
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13.2 Polarization 597After substitu
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13.2 Polarization 599zFIGURE 13-4Po
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13.3 Scattering Matrix 601left-hand
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604 CHAPTER 13 Introduction to Rada
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13.4 Radar Applications of Polarime
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13.4 Radar Applications of Polarime
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13.5 Measurement of the Scattering
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13.5 Measurement of the Scattering
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13.8 References 623• Lee, Jong-Se
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13.8 References 625[32] Kraus, J.D.
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13.9 Problems 627with the result in
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Automatic Target RecognitionCHAPTER
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14.2 Unified Framework for ATR 633P
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14.3 Metrics and Performance Predic
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14.3 Metrics and Performance Predic
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14.4 Synthetic Aperture Radar 639TA
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14.4 Synthetic Aperture Radar 641Te
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14.4 Synthetic Aperture Radar 64314
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14.4 Synthetic Aperture Radar 645Un
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14.4 Synthetic Aperture Radar 64714
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14.4 Synthetic Aperture Radar 649se
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14.4 Synthetic Aperture Radar 651th
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14.5 Inverse Synthetic Aperture Rad
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14.5 Inverse Synthetic Aperture Rad
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14.6 Passive Radar ATR 657radar sys
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14.7 High-Resolution Range Profiles
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14.9 Further Reading 661take a targ
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14.10 References 663[19] Q. H. Pham
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14.10 References 665[56] M. Martore
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14.10 References 667[92] E. Libby,
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Multitarget, MultisensorTrackingCHA
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15.1 Review Of Tracking Concepts 67
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15.1 Review Of Tracking Concepts 67
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678 CHAPTER 15 Multitarget, Multise
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15.2 Multitarget Tracking 683TABLE
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15.2 Multitarget Tracking 685remove
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15.5 Further Reading 69515.4 SUMMAR
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15.6 References 697[11] Blair, W.D.
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15.7 Problems 6992. Common metrics
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⎡⎤3 0 0 0 0 00 3 0 0 0 0P 2 =0
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Human Detection With Radar:Dismount
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environment that may mask the gener
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D s % = Boulic-Thalmann model param
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16.2 Characterizing the Human Radar
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714 CHAPTER 16 Human Detection With
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16.4 Technical Challenges in Human
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16.4 Technical Challenges in Human
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16.5 Exploiting Knowledge for Detec
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16.7 Further Reading 729enable not
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16.8 References 731[13] Broggi, A.,
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16.8 References 733[53] G.E. Smith,
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16.8 References 735Conference on So
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16.9 Problems 737FIGURE 16-13Pendul
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740 CHAPTER 17 Advanced Processing
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17.3 Direct Signal and Multipath/Cl
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17.3 Direct Signal and Multipath/Cl
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17.4 Signal Processing Techniques f
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17.4 Signal Processing Techniques f
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17.5 2D-CCF Sidelobe Control 787TAB
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17.6 Multichannel Processing for De
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17.10 References 815While far from
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17.10 References 817[20] Chetty, K.
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17.11 Problems 819[52] Gao, Z., Tao
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17.11 Problems 8215. Using the sign
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824 Appendix A: Answers to Selected
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ResolutionResolution withDimension
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830 IndexASAR. See Advanced SAR (AS
Page 861 and 862:
832 IndexCross-polarization (XPOL),
Page 863 and 864:
834 IndexExciter-based EP (cont.)fr
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836 IndexInterferencecolored noise,
Page 867 and 868:
838 IndexMoving target indication (
Page 869 and 870:
840 IndexPOI. See Probability of in
Page 871 and 872:
842 IndexSaturated (constant amplit
Page 873 and 874:
844 IndexStripmap SAR (cont.)remote
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846 IndexWWald sequential test, com
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