Abstract
Along with the development of SAR technique, imaging function cannot satisfy the requirement of the application of SAR systems in military and civil areas. Multi-function has become an important tendency of SAR. In this chapter, the development of SAR systems, GMTI and GMTIm algorithms are introduced, and the structure of this book is shown.
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Liu Y (2003) Radar imaging technology. Harbin Institute of Technology Press, Harbin
Zhang Z (1989) Principle, system and application of synthetic aperture radar. Science Press, Beijing
Bao Z, Xing M, Wang T (2005) Radar imaging technology. Publishing House of Electronics industry, Beijing
Mehrdad S (1999) Synthetic aperture radar signal processing with Matlab algorithms. Wiley
Curlander JC, McDonough RN (2006) Synthecia aperture radar–systems & signal processing. Publishing House of Electronics industry, Beijing
Qu C, He Y, Gong S (2002) Development of airborne SAR. Mod Radar 24(1):1–14
William MB (1967) Synthetic aperture radar. IEEE Trans Aerosp Electron Syst 3(2):217–229
Wiley CA (1985) Synthetic aperture radar. IEEE Trans Aerosp Electron Syst 21(3):440–443
Sherwin CW, Ruina JP, Raweliffe RD (1962) Some early developments in synthetic aperture radar system. IRE Trans Mil Electron 6(2):111–115
Skolnik MI (1985) Fifty years of radar. Proc IEEE 73:182–197
Wang J, Liu J, Yuan Y et al (2009) Research on application of unmanned aerial vehicles borne SAR. In: APSAR, 2009, pp 60–63
Li Y, Liang F, Song Q et al (2011) Lever arm rotation compensation for UAV mounted SAR. In: APSAR, 2011, pp 1–3
Wang Y, Xu X, Liu C et al (2010) Airship SAR system for precision microwave measurement of ground targets. J Electron Inf Technol 32(1):28–31
Zhou Q, Qu C, Su F (2008) A new approach of extended Chirp Scaling algorithm for high squint missile-borne SAR data processing. ISCSCT 2:133–136
Yin C, Jia X, Qin W (2009) A novel algorithm for missile borne linear array antenna synthetic aperture radar imaging. In: ICIEA, 2009, pp 1488–1492
Yi Y, Zhang L, Li Y et al (2009) Range Doppler algorithm for bistatic missile-borne forward-looking SAR. In: APSAR, 2009, pp 960–963
Jordan R (1980) The Seasat-A synthetic aperture radar system. IEEE J Oceanic Eng 5(2):154–164
Thompson T, Laderman A (1976) Seasat-A synthetic aperture radar. Radar System Implementation. OCEANS 8:247–251
Zhao Y (2007) Ground moving target indication of synthetic aperture radar. Institute of Electronics, Chinese Academy of Sciences
Li Y (2012) Motion error estimation and compensation of airborne SAR. Institute of Electronics, Chinese Academy of Sciences
Hu J (2012) Signal processing and imaging in multi-channel SAR systems. Institute of Electronics, Chinese Academy of Sciences
Wehner DR (1995) High-resolution radar, 2nd edn. Artech House, Norwood
Mancini P, Suchail JL, Desnos YL et al (1996) The development of the Envisat-1 advanced synthetic aperture radar. In: IEEE international geoscience and remote sensing symposium, 1996, pp 1355–1357
Desnos YL, Laur H (1999) The Envisat-1 advanced synthetic aperture radar processor and data products. In: IEEE international geoscience and remote sensing symposium, 1999, pp 1683–1685
Julien C, Monique B, Gaetan L (2003) RADARSET-1 SAR scenes for wind power mapping in coastal area: Gulf of St-Lawrence case. In: IEEE international geoscience and remote sensing symposium, 2003, pp 2700–2702
Steven I, Greta B (2004) RADARSAT-1: Canadian space agency hurricane watch program. In: IEEE international geoscience and remote sensing symposium, 2004, pp 2742–2745
Livingstone C (1998). The addition of MTI modes to commercial SAR satellites. In: Proceedings of 10th CASI conference on Astronautics, Ottawa, Canada, 1998, pp 26–28
Luscombe A (1995) The Radarsat project. In: IEEE Canadian Review, 1995
Buckreuss S, Balzer W, Muhlbauer P (2003) The TerraSAR-X satellite project. In: IEEE international geoscience and remote sensing symposium, 2003, vol 5, pp 3096–3098
Stangl M, Werninghaus R, Schwerizer B et al (2006) TerraSAR-X technologies and first results. IEE Proc Radar Sonar Navig 153(2):86–95
Marco S, David H, Benjamin B et al (2005) TerraSAR-X: Calibration concept of a multiple mode high resolution SAR. In: IEEE international geoscience and remote sensing symposium, 2005, pp 4874–4877
Alberto M, Gerhard K, Irena H et al (2004) TanDEM-X: A TerraSAR-X add-on satellite for single-pass SAR interferometry. In: IEEE international geoscience and remote sensing symposium, 2004, pp 1000–1003
Zhang M (2012) Motion error compensation of multi-channel SAR system. Institute of Electronics, Chinese Academy of Sciences
Wu X (2012) Signal processing and imaging of random noise radar. Institute of Electronics, Chinese Academy of Sciences
“Lynx Synthetic Aperture Radar”, http://www.sandia.gov/radar/lynx.html
Tsunoda SI, Pace F, Stence J, Woodring M (2000) Lynx: A high-resolution synthetic aperture radar, pp 51–58
Sweet AD, Dubbert DF, Doerry AW, Sloan GR, Dee Gutierrez GR (2006) A portfolio of fine resolution Ku-band miniSAR images: part I. In: Proceedings of SPIE 6210. Radar Sensor Technology X, 6210, May 2006
Cantalloube HMJ, Fernandez PD (2003) Airborne X-band SAR imaging with 10 cm resolution—technical challenge and preliminary results. In: IEEE international geoscience and remote sensing symposium, 2003, pp 185–187
Brenner AR, Roessing L (2008) Radar imaging of urban areas by means of very high-resolution SAR and interferometric SAR. IEEE Trans Geosci Remote Sens 46(10):2917–2982
Ender JHG, Brenner AR (2003) PAMIR-A wideband phased array SAR/MTI system. IEE Proc Radar Sonar Navig 150(3):165–172
Cerutti-Maori D, Klare J, Brenner AR et al (2008) Wide-area traffic monitoring with the SAR/GMTI system PAMIR. IEEE Trans Geosci Remote Sens 46(10):3019–3030
Brenner AR, Ender JHG (2006) Demonstration of advanced reconnaissance techniques with the airborne SAR/GMTI sensor PAMIR. IEEE Trans Geosci Remote Sens 153(2):152–162
Brenner AR (2010) Proof of concept for airborne SAR imaging with 5 cm resolution in X-band. In: EUSAR, 2010, pp 615–618
Jakowatz CV, Wahl DE, Eichel PH et al (1996) Spotlight-mode synthetic aperture radar: a signal processing approach. Kluwer Academic Publishers, Boston
Carrara WG, Goodman RS, Majewdki RM (1995) Spotlight synthetic aperture radar-signal processing algorithms. Artech House, Norwood
Zhu D, Zhu Z (2007) Range Resampling in the polar format algorithm for spotlight SAR image formation using the Chirp-Z transform. IEEE Trans Signal Process 55(3):1011–1023
Belcher DP, Baker CJ (1995) High resolution processing of hybrid strip-map/spotlight mode SAR. IEE Proc Radar Sonar Navig 143(6):366–374
Franceschetti G, Guida R, Iodice A et al (2004) Efficient simulation of hybrid stripmap/spotlight SAR raw signals from extended scenes. IEEE Trans Geosci Remote Sens 42(11):2385–2396
Lanari R, Zoffoli S, Sansosti E et al (2001) New approach for hybrid strip-map/spotlight SAR data focusing. IEE Proc Radar Sonar Navig 148(6):363–372
Ferraiuolo G, Meglio F, Pascazio V et al (2009) DEM reconstruction accuracy in multichannel SAR interferometry. IEEE Trans Geosci Remote Sens 42(11):2385–2396
Ferretti A, Prati C, Rocca F (1999) Multibaseline InSAR DEM reconstruction: the wavelet approach. IEEE Trans Geosci Remote Sens 37(2):705–715
Lanari R, Fornaro G, Riccio D et al (1996) Generation of digital elevation models by using SIR-C/X-SAR multifrequency two-pass interferometry: the Etna case study. IEEE Trans Geosci Remote Sens 34(5):1097–1114
Hansen RC (2009) Phased array antennas. John Wiley & Sons Inc, NJ
Li G, Xu J, Peng Y et al (2007) Location and imaging of moving targets using nonuniform linear antenna array SAR. IEEE Trans Aerosp Electron Syst 43(3):1214–1220
Ender JHG, Klare J (2009) System architectures and algorithms for radar imaging by MIMO-SAR. In: IEEE Radar Conference, Pasadena, CA, May 2009, pp 1–6
Edrich M (2004) Design overview and flight test results of the miniaturized SAR sensor MISAR. In: EURAD, Amsterdam, Netherlands, Oct 2004, pp 205–208
Edrich M (2006) Ultra-lightweight synthetic aperture radar based on a 35 GHz FMCW sensor concept and online raw data transmission. IEE Proc Radar Sonar Navig 153(2):129–134
Zaugg EC, Hudson DL, Long DG (2006) The BYU mu SAR: a small, student-built SAR for UAV operation. In: IEEE international geoscience and remote sensing symposium, 2006, pp 411–414
Zaugg EC, Long DG (2008) Theory and application of motion compensation for LFM-CW SAR. IEEE Trans Geosci Remote Sens 46(10):2990–2998
Garester F, Dubois-Fernandez PC, Guyon D et al (2009) Forest biophysical parameter estimation using L- and P-band polarimetric SAR data. IEEE Trans Geosci Remote Sens 47(10):3379–3388
Ding L, Geng F (2000) Radar principle. Xidian University Press, Xi’an
Clarke J (1985) Airborne early warning radar. Proc IEEE 73(2):312–324
Morchin WC, Johnston SL (1991) Modern airborne early warning radars. Microwave J 30–47. Academic OneFile. Accessed 1 Jan 2017
Tobin ME, Greenspan M (1996) Adaptation of AN/APG-76 multimode radar to the smuggling interdiction mission. In: IEEE national radar conference, Ann Arbor, Michigan, May 1996, pp 13–18
Tobin ME, Greenspan M (1996) Smuggling interdiction using an adaptation of the AN/APG-76 multimode radar. IEEE Aerosp Electron Syst Mag 11(11):19–24
Richard JD (2004) Ground moving target indicator radar and the transformation of U.S. warfighting, Northrop Grumman, Feb 2004
Bayma RW (1996) Hughes integrated synthetic aperture radar. In: IEEE international geoscience and remote sensing symposium, 1996, vol 3, pp 1615–1617
Liu C (2006) Real-time signal processing of airborne SAR/GMTI systems. Institute of Electronics, Chinese Academy of Sciences
Zheng M (2003) Moving target indication and imaging of synthetic aperture radar. Institute of Electronics, Chinese Academy of Sciences
Kang X (2004) Gournd moving target indication and imaging of airborne SAR. Institute of Electronics, Chinese Academy of Sciences
Raney RK (1971) Synthetic aperture imaging radar and moving target. IEEE Trans Aerosp Electron Syst 7:499–505
Chen H, McGillem CD (1992) Target motion compensation by spectrum shifting in synthetic aperture radar. IEEE Trans Aerosp Electron Syst 28(3):119–125
Freeman A (1984) Simple MTI using synthetic aperture radar. In: IEEE international geoscience and remote sensing symposium, 1984, pp 65–70
Fienup JR (2001) Detection of moving targets in SAR imagery by focusing. IEEE Trans Aerosp Electron Syst 37(3):794–809
Moreira J, Keydel W (1995) A new MTI-SAR approach using the reflectivity displacement method. IEEE Trans Geosci Remote Sens 33(5):1238–1244
Barbarossa S (1992) Detection and imaging of moving objects with synthetic aperture radar, part I: optimal detection and parameter estimation theory. IEE Proceeds-F 139(1):79–88
Barbarossa S, Farina A (1992) Detection and imaging of moving objects with synthetic aperture radar, part II: joint time-frequency analysis by Wigner-Ville distribution. IEE Proceeds-F 139(1):89–97
Liu F, Sun D, Huang Y et al (2009) Fast parameter-estimation of LFM signal based on improved combined WVD and randomized Hough transform. ACTA Armamentarii 30(12):1642–1646
Liu J, Wang X, Liu Z et al (2007) Detection performance of linear frequency modulated signals based on Wigner-Hough transform. ACTA Electronica Sin 35(6):1212–1217
Kirscht M (1996) Detection and velocity estimation of moving objects in a sequence of single-look SAR images. In: IEEE international geoscience and remote sensing symposium, 1996, Lincoln, Nebraska, USA, pp 333–335
Dias J, Marques P (2003) Multiple moving target detection and trajectory estimation using a single SAR sensor. IEEE Trans Aerosp Electron Syst 39(2):604–624
Li L, Si X, Chai J et al (2009) Parameters estimation for LFM radar signal based on reassigned wavelet-Radon transform. Syst Eng Electron 31(1):74–77
Li G, Zhu H (2001) Airborne SAR moving target parameter estimation based on extended wavelet transform. J Electron Inf Technol 23(11):1154–1161
Fante RL (1989) Analysis of the Displaced-Phase-Center radar for clutter reduction. Mitre Corporation Report, Aug 1989, MT10666
Lightstone L (1944) Antenna distortions in multiple phase centre interferometric systems. In: IEEE international geoscience and remote sensing symposium, Aug 1944, vol 4, pp 1980–1982
Wang HSC (1991) Mainlobe clutter cancellation by DPCA for space-based radars. In: Aerospace applications conference, 1991. Digest., 1991 IEEE, Feb 1991, pp 1–128
Stockburger E, Held (DN) Interferometric ground moving target imaging. In: IEEE international radar conference, 1995, 438–443
Soumekh M (1997) Moving target detection in Foliage using along track monopulse synthetic aperture radar imaging. IEEE Trans Image Process 6(8):1148–1163
Moccia A, Rufino G (2001) Spaceborne along-track SAR interferometry: performance analysis and mission scenarios. IEEE Trans Aerosp Electron Syst 37(1):199–213
Brennan LE, Reed IS (1973) Theory of adaptive radar. IEEE Trans Aerosp Electron Syst 9(3):237–252
Ender JHG (1999) Space-time processing for multichannel synthetic aperture radar. Electron Commun Eng J 11(1):29–38
Gerlach K, Picciolo ML (2003) Airborne/Spacebased radar STAP using a structured covariance matrix. IEEE Trans Aerosp Electron Syst 39(1):269–281
Zhao F (2013) Muli-channel SAR imaging and moving target indication technique. Institute of electronics, Chinese Academy of Sciences
Yu B (2013) FMCW-SAR signal processing and imaging technique. Institute of electronics, Chinese Academy of Sciences
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Yang, J. (2017). Introduction. In: Study on Ground Moving Target Indication and Imaging Technique of Airborne SAR. Springer Theses. Springer, Singapore. https://doi.org/10.1007/978-981-10-3075-8_1
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