Principles of Modern Radar - Volume 2 1891121537

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5.8 References 203[116] Eldar, Y.C. and Mishali, M., “Robust Recovery of Signals from a Structured Union ofSubspaces,” IEEE Transactions on Information Theory, vol. 55, pp. 5302–5316, November2009.[117] Schniter, P., “Turbo Reconstruction of Structured Sparse Signals,” ICASSP, 2010.[118] Koetter, R., Singer, A., and Tuchler, M., “Turbo Equalization,” IEEE Signal ProcessingMagazine, vol. 21, pp. 67–80, January 2004.[119] Candès, E. and Recht, B., “Exact Matrix Completion via Convex Optimization,” Arxivpreprint arXiv:0805.44, 2008.[120] Candès, E., Li, X., Ma, Y., and Wright, J., “Robust Principal Component Analysis?:Recovering Low-Rank Matrices from Sparse Errors,” in Proceedings of the IEEE SensorArray and Multichannel Signal Processing Workshop, pp. 201–204, 2010.[121] Tao, M. and Yuan, X., “Recovering Low-Rank and Sparse Components of Matrices fromIncomplete and Noisy Observations,” SIAM Journal on Optimization, vol. 21, no. 1, pp.57–81, 2011.[122] Cao, G. and Bouman, C.A., “Covariance Estimation for High Dimensional Data VectorsUsing the Sparse Matrix Transform,” in Proceedings of Neural Information ProcessingSystems Conference, December 2008.[123] Malioutov, D., Cetin, M., and Willsky, A.S., “A Sparse Signal Reconstruction Perspectivefor Source Localization with Sensor Arrays,” IEEE Transactions on Signal Processing, vol.53, pp. 3010–3022, August 2005.[124] Chi, Y., Pezeshki, A., Scharf, L., and Calderbank, R., “Sensitivity to Basis Mismatch inCompressed Sensing,” in Proceedings of the IEEE International Acoustics Speech andSignal Processing Conference, pp. 3930–3933, 2010.[125] Zhu, H., Leus, G., and Giannakis, G., “Sparsity-Cognizant Total Least-Squares for PerturbedCompressive Sampling,” IEEE Transactions on Signal Processing, vol. 59, pp. 2002–2016,May 2011.[126] Herman, M.A. and Strohmer, T., “General Deviants: An Analysis of Perturbations inCompressed Sensing,” IEEE Journal of Selected Topics in Signal Processing, vol. 4, no. 2,pp. 342–349, 2010.[127] Rosenbaum, M. and Tsybakov, A., “Sparse Recovery under Matrix Uncertainty,” Annals ofStatistics, vol. 38, no. 5, pp. 2620–2651, 2010.[128] Parker, J.T., Cevher, V., and Schniter, P., “Compressive Sensing under Matrix Uncertainties:An Approximate Message Passing Approach,” in Proceedings of Asilomar Conference onSignals, Systems, and Computers, November 2011.[129] Tosic, I. and Frossard, P., “Dictionary Learning,” IEEE Signal Processing Magazine, vol.28, pp. 27–38, March 2011.[130] Goldstein, T. and Osher, S., “The Split Bregman Method for l 1 -Regularized Problems,”SIAM Journal on Imaging Sciences, vol. 2, p. 323, 2009.[131] Yin, W., Osher, S., Goldfarb, D., and Darbon, J., “Bregman Iterative Algorithms forl 1 -Minimization with Applications to Compressed Sensing,” SIAM Journal on ImagingSciences, vol. 1, no. 1, pp. 143–168, 2008.[132] Rice University, “Compressive Sensing Resources.” Available at http://dsp.rice.edu/cs.[133] Gurbuz, A.C., McClellan, J.H., and Scott Jr., R., “A Compressive Sensing Data Acquisitionand Imaging Method for Stepped Frequency GPRs,” IEEE Transactions on SignalProcessing, pp. 1–1, 2009.
204 CHAPTER 5 Radar Applications of Sparse Reconstruction[134] Bhattacharya, S., Blumensath, T., Mulgrew, B., and Davies, M., “Fast Encoding of SyntheticAperture Radar Raw Data Using Compressed Sensing,” in Proceedings of the IEEE/SP 14thWorkshop on Statistical Signal Processing, pp. 448–452, August 26–29, 2007.[135] Novak, L., “The Effects of SAR Data Compression on Coherent and Non-coherent ChangeDetection,” in IEEE International Radar Conference, 2009.[136] Patel, V.M., Easley, G.R., Dennis, J. Healy, M., and Chellappa, R., “Compressed SyntheticAperture Radar,” IEEE Journal of Selected Topics in Signal Processing, vol. 4, pp. 244–254,April 2010.[137] Baraniuk, R. and Steeghs, P., “Compressive Radar Imaging,” in Proceedings of the IEEERadar Conference, pp. 128–133, April 17–20, 2007.[138] Romberg, J., “Compressive Sensing by Random Convolution,” SIAM Journal on ImagingSciences, vol. 2, no. 4, pp. 1098–1128, 2009.[139] Eldar, Y., “Compressed Sensing of Analog Signals in Shift-Invariant Spaces,” IEEETransactions on Signal Processing, vol. 57, pp. 2986–2997, August 2009.[140] Ross, T., Worrell, S., Velten, V., Mossing, J., and Bryant, M., “Standard SAR ATR EvaluationExperiments Using the MSTAR Public Release Data Set,” in Proceedings of the SPIE:Algorithms for Synthetic Aperture Radar Imagery V, Orlando, FL, pp. 566–573, 1998.[141] Varshney, K.R., Cetin, M., Fisher, J.W., and Willsky, A.S., “Sparse Representation inStructured Dictionaries with Application to Synthetic Aperture Radar,” IEEE Transactionson Signal Processing, vol. 56, pp. 3548–3561, August 2008.[142] Ji, S., Xue, Y., and Carin, L., “Bayesian Compressive Sensing,” IEEE Transactions onSignal Processing, vol. 56, no. 6, pp. 2346–2356, 2008.[143] Angelosante, D., Giannakis, G.B., and Grossi, E., “Compressed Sensing of Time-VaryingSignals,” in International Conference on Digital Signal Processing, pp. 1–8, July 2009.[144] Vaswani, N. and Lu, W., “Modified-CS: Modifying compressive sensing for problems withpartially known support,” IEEE Transactions on Signal Processing, vol. 58, pp. 4595–4607,September 2010.[145] Ziniel, J., Potter, L.C., and Schniter, P., “Tracking and Smoothing of Time-Varying SparseSignals via Approximate Belief Propagation,” in Asilomar Conf. on Signals, Systems andComputers, Pacific Grove, CA, November 2010.[146] Naidu, K. and Lin, L., “Data Dome: Full k-Space Sampling Data for High Frequency RadarResearch,” Pp. 200–207in Algorithms for Synthetic Aperture Radar Imagery XI, vol. 5427,Ed. E.G. Zelnio and F.D. Garber, SPIE, 2004.[147] Air Force Research Laboratory, “Virtual Distributed Laboratory.” Available athttps://www.vdl.afrl.af.mil/.[148] Stuff, M.A., “Three-Dimensional Analysis of Moving Target Radar Signals: Methods andimplications for ATR and feature aided tracking,” pp. 485–496 in Algorithms for SyntheticAperture Radar Imagery VI, vol. 3721, Ed. E.G. Zelnio, Proceedings of SPIE, 1999.[149] Stuff, M.A., Sanchez, P., and Biancalana, M., “Extraction of Three-Dimensional Motionand Geometric Invariants from Range Dependent Signals,” Multidimensional Systems ofSignal Processing, vol. 14, nos. 1–3, pp. 161–181, 2003.[150] Keller, J.B., “Geometrical Theory of Diffraction,” Journal of the Optical Society of America,pp. 116–130, January 1962.[151] Potter, L.C., Chiang, D., Carriere, R., and Gerry, M.J.., “A GTD-Based Parametric Modelfor Radar Scattering,” IEEE Transactions on Antennas and Propagation, vol. 43, no. 10,pp. 1058–1067, 1995.
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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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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 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
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254 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
Page 875 and 876:
846 IndexWWald sequential test, com
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