Principles of Modern Radar - Volume 2 1891121537

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14.9 Further Reading 661take a target cross sectional length measurement from the HRRP as an input and map it toa set of aspect angles. Those angles are then compared with the kinematics measurementsto find the angle that is most consistent, and thus minimizes the filter residual.Several authors have taken a more mathematical approach and started with the eigenvalueor singular value decomposition (SVD) of the HRRPs, followed by eigenvalue orsingular value template matching [85, 93–97]. These matrix decomposition approachesexploit structure in the data. In general, a dominant eigenvector accounts for 90% of the target’senergy, and the range and angle bias spaces are numerically decoupled in the left andright eigenvectors [98]. Further, using Principal Component Analysis (PCA) to eliminateeigenvectors of small eigenvalues can lead to clutter suppression [93]. Likewise the SVDallows for projection of the HRRP onto orthogonal basis spaces (this is Karhunen-Loevetransformation or again, PCA), like in the Baseline Automated Recognition of Targets(BART) proposed by Kahler and Blasch [96].Nguyen, et al. [99] proposed High Definition Vector Imaging (HDVI), a superresolutiontechnique. They apply HDVI to HRRPs before using the profiles for ATR classification.They argue this approach requires fewer computations than weighted fast Fouriertransforms and can improve recognition over traditional image processing techniques.14.8 SUMMARYA wide variety of radar-based ATR systems and applications have been developed anddocumented in open literature. As different as these may seem on the surface, they alltend to revolve around four basic steps, labeled in this chapter as the unified frameworkfor ATR. First, the target set must be identified. Then the feature set must be selected,observed, and tested to identify the targets. The most challenging parts of the problemtend to be predicting all likely target variations and discerning a feature set that sufficientlysegregates the target set while being readily observable.14.9 FURTHER READINGRecommended further reading focus on the computational aspects of database formationand access, which are outside the scope of this chapter. A fundamental tradeoff existsbetween the desired performance (and associated degree of fidelity required in the targetdatabase) and the amount of available computing power. More information can improverobustness, but it also implies increased computational demands. One approach is toemploy a traditional clustering technique (such as k-means clustering algorithm [86]) toreduce the number of signatures in the database. High performance computing may alsobe required to deliver results that are both sufficiently reliable and timely.A significant number of papers address the problems of ATR in a theoretical sense,but actual implementation of their ideas is not always straightforward. For example, [77][78] assume their MTI tracker can compute target aspect angles within ± 15 ◦ . This assumptionmeans that fewer angles need to be stored in their database. They also assumethat their templates and observations can be aligned and normalized. Other authors makeassumptions about the data collection, including that the flight path of the radar is constantvelocity and roll angle of 0 ◦ .
662 CHAPTER 14 Automatic Target Recognition14.10 REFERENCES[1] L. M. Novak, S. D. Halversen, G. J. Owirka and M. Hiett, “Effects of Polarization andResolution on the Performance of a SAR Automatic Target Recognition System,” The LincolnLaboratory Journal, vol. 8, no. 1, pp. 49–68, 1995.[2] M. Vespe, C. J. Baker and H. D. Griffiths, “Automatic target recognition using multi-diversityradar,” IET Radar Sonar Navig., vol. 1, no. 6, pp. 470–478, 2007.[3] A. E. Catlin, “System Comparison Procedures for Automatic Target Recognition Systems,”Air Force Institute of Technology, Wright Patterson AFB, OH, 1997.[4] R. Hummel, “Model-Based ATR Using Synthetic Aperture Radar,” in IEEE InternationalRadar Conference, 2000.[5] T. D. Ross and J. C. Mossing, “The MSTAR Evaluation Methodology,” in Algorithms forSynthetic Aperture Radar Imagery VI Proceedings of the SPIE, Orlando, FL, 1999.[6] T. D. Ross, L. A. Westerkamp, D. A. Gadd and R. B. Kotz, “Feature and Extractor EvaluationConcepts for Automatic Target Recognition (ATR),” Wright Laboratory, Wright-PattersonAFB, OH, 1995.[7] L. M. Novak, G. J. Owirka and A. L. Weaver, “Automatic Target Recognition Using EnhancedResolutions SAR Data,” IEEE Transactions on Aerospace and Electronic Systems, vol. 35,no. 1, pp. 157–175, 1999.[8] L. Westerkamp, S. Morrison, T. Wild and J. Mossing, “High-resolution synthetic apertureradar experiments for ATR development and performance prediction,” in Proceedings ofSPIE: Algorithms for Synthetic Aperture Radar Imagery IX, 2002.[9] A. K. Mishra and B. Mulgrew, “Multipolar SAR ATR: Experiments with the GTRI Dataset,”in IEEE Radar Conference, 2008.[10] European Aeronautic Defence and Space Company, “Generation of Synthetic SAR Imageryfor ATR Development,” European Aeronautic Defence and Space Company, Munich,Germany, 2005.[11] C. J. Beaudoin, A. J. Gatesman, R. H. Giles, J. Waldman and W. E. Nixon, “A 3D PolarProcessing Algorithm for Scale Model UHF ISAR Imaging,” University of MassachusettsLowell, Submillimeter-Wave Technology Laboratory, Lowell, MA, 2006.[12] L. M. Novak, G. J. Owirka and C. M. Netishen, “Performance of a High-Resolution PolarimetricSAR Automatic Target Recognition System,” vol. 6, no. 1, pp. 11–24, 1993.[13] A. K. Mishra, “Validation of PCA and LDA for SAR ATR,” in IEEE Region 10 Conference,2008.[14] A. K. Mishra and B. Mulgrew, “Multipolar SAR ATR: Experiments with the GTRI Dataset,”in IEEE Radar Conference, 2008.[15] A. K. Mishra and B. Mulgrew, “Bistatic SAR ATR,” IET Radar Sonar Navig., vol. 1, no. 6,pp. 459–469, 2007.[16] E. Seidenberg and H. Schimpf, “Aspects of Automatic Target Recognition with a Two-Frequency Millimeter Wave SAR,” in Radar Sensor Technology V Proceedings of SPIE,2000.[17] V. Sabio, “Target Recognition in Ultra-Wideband SAR Imagery,” U.S. Army ResearchLaboratory, Adelphi, MD, 1994.[18] A. J. Bennett and A. Currie, “The Use of High Resolution Polarimetric SAR for AutomaticTarget Recognition,” in Proceedings of SPIE, 2002.
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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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5.2 CS Theory 163While the notion o
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5.2 CS Theory 165as , where is a b
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5.3 SR Algorithms 167than the norm
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5.3 SR Algorithms 169the value of o
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5.3 SR Algorithms 171takes special
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5.3 SR Algorithms 173The function f
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5.3 SR Algorithms 175of the TV norm
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5.3 SR Algorithms 177One can argue
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5.3 SR Algorithms 179probability ma
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5.3 SR Algorithms 181only a subset
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5.4 Sample Radar Applications 183pr
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5.4 Sample Radar Applications 185We
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5.4 Sample Radar Applications 187th
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5.4 Sample Radar Applications 189tu
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5.4 Sample Radar Applications 191Ra
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5.4 Sample Radar Applications 193Ta
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Spotlight SyntheticAperture RadarCH
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6.1 Introduction 213• Image quali
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6.2 Mathematical Background 215andf
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6.2 Mathematical Background 2172π
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220 CHAPTER 6 Spotlight Synthetic A
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6.4 Sampling Requirements and Resol
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6.4 Sampling Requirements and Resol
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6.5 Image Reconstruction 239FIGURE
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6.6 Image Metrics 241The contrast r
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6.6 Image Metrics 243Along-track am
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6.7 Phase Error Effects 245TABLE 6-
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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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10.5 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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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 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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17.11 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
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832 IndexCross-polarization (XPOL),
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834 IndexExciter-based EP (cont.)fr
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836 IndexInterferencecolored noise,
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838 IndexMoving target indication (
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840 IndexPOI. See Probability of in
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842 IndexSaturated (constant amplit
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844 IndexStripmap SAR (cont.)remote
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846 IndexWWald sequential test, com
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