4.12.6 Spotlight Radar, Spotlight SAR

di Cenzo, A.,
A Comparison of Resolution for Spotlight Synthetic-Aperture Radar and Computer-Aided Tomography,
PIEEE(74), 1986, pp. 1165-1166. BibRef 8600

Desai, M.D., Jenkins, W.K.,
Convolution backprojection image reconstruction for spotlight mode synthetic aperture radar,
IP(1), No. 4, October 1992, pp. 505-517.
IEEE DOI 0402
BibRef

Desai, M.D.,
Spotlight Mode SAR Stereo Technique for Height Computation,
IP(6), No. 10, October 1997, pp. 1400-1411.
IEEE DOI 9710
BibRef

Soumekh, M.,
Signal Subspace Fusion of Uncalibrated Sensors with Application in SAR and Diagnostic Medicine,
IP(8), No. 1, January 1999, pp. 127-137.
IEEE DOI BibRef 9901
Earlier:
Signal Subspace Fusion of Uncalibrated Sensors with Application in SAR, Diagnostic Medicine and Video Processing,
ICIP97(III: 280-283).
IEEE DOI BibRef
Earlier:
FM-CW SAR and phased array spatial-velocity imaging,
ICIP94(I: 471-475).
IEEE DOI 9411
BibRef

Soumekh, M., Choi, J.H.,
Phase and amplitude phase restoration in synthetic aperture radar imaging,
IP(1), No. 2, April 1992, pp. 229-242.
IEEE DOI 0402
BibRef

Soumekh, M., Acharya, R., Kriman, A.,
Range-speed imaging with FM-CW signaling,
ICPR94(A:529-531).
IEEE DOI 9410
BibRef

Soumekh, M.,
Digital spotlighting and coherent subaperture image formation for stripmap synthetic aperture radar,
ICIP94(I: 476-480).
IEEE DOI 9411
BibRef

Webb, J.L.H., Munson, Jr., D.C., Stacy, N.J.S.,
High-resolution Planetary Imaging via Spotlight-mode Synthetic Aperture Radar,
IP(7), No. 11, November 1998, pp. 1571-1582.
IEEE DOI BibRef 9811
Earlier: ICIP94(I: 451-455).
IEEE DOI 9411
BibRef

Webb, J.L.H., Munson, Jr., D.C.,
Radar imaging of three-dimensional surfaces using limited data,
ICIP95(I: 136-139).
IEEE DOI 9510
BibRef

Lee, J.A.[Jung Ah], Munson, Jr., D.C.[David C.],
Runway Imaging from an Approaching Aircraft Using Synthetic Aperture Radar,
ICIP96(III: 915-918).
IEEE DOI BibRef 9600

Cadalli, N., Munson, Jr., D.C.,
A Comparison of Omega-k and Generalized SAR Inversion for Runway Imaging,
ICIP00(Vol I: 693-696).
IEEE DOI 0008
BibRef

Lee, J.A.[Jung Ah], Munson, Jr., D.C.[David C.],
Effect of a nonplanar wavefront in spotlight-mode synthetic aperture radar,
ICIP94(I: 481-485).
IEEE DOI 9411
BibRef

Yeo, T.S., Zhang, C.B., Lu, Y.H.,
Correction of geometric distortion in spotlight synthetic aperture radar imagery,
JRS(20), No. 5, March 1999, pp. 979. BibRef 9903

Mittermayer, J., Moreira, A., Loffeld, O.,
Spotlight SAR Data Processing Using the Frequency Scaling Algorithm,
GeoRS(37), No. 5, September 1999, pp. 2198.
IEEE Top Reference. BibRef 9909

Cimmino, S., Franceschetti, G., Iodice, A., Riccio, D., Ruello, G.,
Efficient spotlight SAR raw signal simulation of extended scenes,
GeoRS(41), No. 10, October 2003, pp. 2329-2337.
IEEE Abstract. 0310
BibRef

Franceschetti, G., Iodice, A., Perna, S., Riccio, D.,
Efficient Simulation of Airborne SAR Raw Data of Extended Scenes,
GeoRS(44), No. 10, October 2006, pp. 2851-2860.
IEEE DOI 0609
BibRef

Franceschetti, G., Iodice, A., Perna, S., Riccio, D.,
SAR Sensor Trajectory Deviations: Fourier Domain Formulation and Extended Scene Simulation of Raw Signal,
GeoRS(44), No. 9, September 2006, pp. 2323-2334.
IEEE DOI 0609
BibRef

Xu, W., Huang, P., Wang, R., Deng, Y.,
Processing of Multichannel Sliding Spotlight and TOPS Synthetic Aperture Radar Data,
GeoRS(51), No. 8, 2013, pp. 4417-4429.
IEEE DOI 1307
Multichannel BibRef

Prats, P., Scheiber, R., Mittermayer, J., Meta, A., Moreira, A.,
Processing of Sliding Spotlight and TOPS SAR Data Using Baseband Azimuth Scaling,
GeoRS(48), No. 2, February 2010, pp. 770-780.
IEEE DOI 1002
BibRef

Owens, J.W., Marcellin, M.W.,
Rate Allocation for Spotlight SAR Phase History Data Compression,
IP(8), No. 11, November 1999, pp. 1527-1533.
IEEE DOI 9911
BibRef

Lanari, R., Tesauro, M., Sansosti, E., Fornaro, G.,
Spotlight SAR data focusing based on a two-step processing approach,
GeoRS(39), No. 9, September 2001, pp. 1993-2004.
IEEE Top Reference. 0111
BibRef

Chan, H.L., Yeo, T.S.,
Comments on 'non-iterative quality phase-gradient autofocus (QPGA) algorithm for spotlight SAR imagery',
GeoRS(40), No. 11, November 2002, pp. 2517-2517.
IEEE Top Reference. 0301
BibRef

Wong, F.H., Yeo, T.S.[Tat Soon],
A novel technique for the processing of short-dwell spotlight SAR data,
GeoRS(41), No. 5, May 2003, pp. 953-963.
IEEE Abstract. 0307
BibRef

Mittermayer, J., Wollstadt, S., Prats-Iraola, P., Scheiber, R.,
The TerraSAR-X Staring Spotlight Mode Concept,
GeoRS(52), No. 6, June 2014, pp. 3695-3706.
IEEE DOI 1403
Antennas BibRef

Mittermayer, J., Kraus, T., López-Dekker, P., Prats-Iraola, P., Krieger, G., Moreira, A.,
Wrapped Staring Spotlight SAR,
GeoRS(54), No. 10, October 2016, pp. 5745-5764.
IEEE DOI 1610
geophysical image processing BibRef

Wu, Y., Sun, G.C., Yang, C., Yang, J., Xing, M., Bao, Z.,
Processing of Very High Resolution Spaceborne Sliding Spotlight SAR Data Using Velocity Scaling,
GeoRS(54), No. 3, March 2016, pp. 1505-1518.
IEEE DOI 1603
Azimuth BibRef

Sun, G.C., Wu, Y., Yang, J., Xing, M., Bao, Z.,
Full-Aperture Focusing of Very High Resolution Spaceborne-Squinted Sliding Spotlight SAR Data,
GeoRS(55), No. 6, June 2017, pp. 3309-3321.
IEEE DOI 1706
Azimuth, Image resolution, Imaging, Orbits, Radar imaging, Spaceborne radar, Synthetic aperture radar, Range model, spaceborne synthetic aperture radar (SAR), squinted sliding spotlight SAR, very, high, resolution BibRef

Yang, W.[Wei], Chen, J.[Jie], Liu, W.[Wei], Wang, P.[Pengbo], Li, C.,
A Modified Three-Step Algorithm for TOPS and Sliding Spotlight SAR Data Processing,
GeoRS(55), No. 12, December 2017, pp. 6910-6921.
IEEE DOI 1712
Antennas, Azimuth, Bandwidth, Chirp, Doppler effect, Imaging, Synthetic aperture radar, Chirp z, sliding spotlight, terrain observation by progressive scans (TOPS) BibRef

Wang, Y.[Yan], Li, J.W.[Jing-Wen], Yang, J.[Jian], Sun, B.[Bing],
A Novel Spaceborne Sliding Spotlight Range Sweep Synthetic Aperture Radar: System and Imaging,
RS(9), No. 8, 2017, pp. xx-yy.
DOI Link 1708
BibRef

Wang, Y.[Yan], Li, J.W.[Jing-Wen], Yang, J.[Jian],
Wide Nonlinear Chirp Scaling Algorithm for Spaceborne Stripmap Range Sweep SAR Imaging,
GeoRS(55), No. 12, December 2017, pp. 6922-6936.
IEEE DOI 1712
Algorithm design and analysis, Azimuth, Doppler effect, Geometry, Imaging, Spaceborne radar, Synthetic aperture radar, wide nonlinear chirp scaling (W-NLCS) BibRef

Mao, X., He, X., Li, D.,
Knowledge-Aided 2-D Autofocus for Spotlight SAR Range Migration Algorithm Imagery,
GeoRS(56), No. 9, September 2018, pp. 5458-5470.
IEEE DOI 1809
Synthetic aperture radar, Azimuth, History, Fourier transforms, Radar antennas, Frequency-domain analysis, Autofocus, synthetic aperture radar BibRef

Hu, R.Z.[Rui-Zhi], Li, X.L.[Xiao-Long], Yeo, T.S.[Tat Soon], Yang, Y.[Yue], Chi, C.[Cheng], Zuo, F.[Feng], Hu, X.Y.[Xian-Yang], Pi, Y.M.[Yi-Ming],
Refocusing and Zoom-In Polar Format Algorithm for Curvilinear Spotlight SAR Imaging on Arbitrary Region of Interest,
GeoRS(57), No. 10, October 2019, pp. 7995-8010.
IEEE DOI 1910
compensation, fast Fourier transforms, image reconstruction, radar imaging, synthetic aperture radar, zoom-in BibRef

Mao, X., Ding, L., Zhang, Y., Zhan, R., Li, S.,
Knowledge-Aided 2-D Autofocus for Spotlight SAR Filtered Backprojection Imagery,
GeoRS(57), No. 11, November 2019, pp. 9041-9058.
IEEE DOI 1911
Synthetic aperture radar, Radar imaging, Radar antennas, Apertures, Frequency-domain analysis, Geometry, 2-D autofocus, synthetic aperture radar (SAR) BibRef

Zeng, T.[Tao], Wang, Z.Z.[Zhan-Ze], Liu, F.F.[Fei-Feng], Wang, C.H.[Cheng-Hao],
An Improved Frequency-Domain Image Formation Algorithm for Mini-UAV-Based Forward-Looking Spotlight BiSAR Systems,
RS(12), No. 17, 2020, pp. xx-yy.
DOI Link 2009
BibRef

Hu, R.Z.[Rui-Zhi], Rao, B.S.M.R.[Bhavani Shankar Mysore Rama], Alaee-Kerahroodi, M.[Mohammad], Ottersten, B.[Björn],
Orthorectified Polar Format Algorithm for Generalized Spotlight SAR Imaging With DEM,
GeoRS(59), No. 5, May 2021, pp. 3999-4007.
IEEE DOI 2104
Imaging, Synthetic aperture radar, Distortion, Radar imaging, Apertures, Radar polarimetry, Digital elevation model (DEM), polar format algorithm (PFA) BibRef

Wang, Y.[Yan], Ding, Z.[Zegang], Xu, P.[Pei], Chen, K.[Ke], Zeng, T.[Tao], Long, T.[Teng],
Strip Layering Diagram-Based Optimum Continuously Varying Pulse Interval Sequence Design for Extremely High-Resolution Spaceborne Sliding Spotlight SAR,
GeoRS(59), No. 8, August 2021, pp. 6751-6770.
IEEE DOI 2108
Strips, Azimuth, Synthetic aperture radar, Spaceborne radar, Timing, Geometry, Apertures, Continuously varying pulse interval (CVPI), strip layering diagram BibRef

Liu, P.[Peng], Li, Z.H.[Zhen-Hong], Wang, C.S.[Chi-Sheng], Chen, K.[Kejie], Chen, X.F.[Xiao-Fei],
Phase unmixing of TerraSAR-X staring spotlight interferograms in building scale for PS height and deformation,
PandRS(180), 2021, pp. 14-28.
Elsevier DOI 2109
TerraSAR-X staring spotlight images, Phase unmixing, PS height, PS point cloud segmentation, Spatial phase unwrapping network segmentation BibRef

Fan, H.T.[Huai-Tao], Zhang, L.[Lei], Zhang, Z.M.[Zhi-Min], Yu, W.D.[Wei-Dong], Deng, Y.K.[Yun-Kai],
On the Processing of Gaofen-3 Spaceborne Dual-Channel Sliding Spotlight SAR Data,
GeoRS(60), 2022, pp. 1-12.
IEEE DOI 2112
Azimuth, Synthetic aperture radar, Phased arrays, Imaging, Antennas, Spaceborne radar, Doppler effect, Gaofen-3 (GF-3), multichannel sliding spotlight synthetic aperture radar (SAR) BibRef

Zhang, Z.N.[Zhen-Ning], Yu, W.D.[Wei-Dong], Zheng, M.J.[Ming-Jie], Zhao, L.B.[Liang-Bo], Zhou, Z.X.[Zi-Xuan],
Phase Mismatch Calibration for Dual-Channel Sliding Spotlight SAR-GMTI,
RS(14), No. 3, 2022, pp. xx-yy.
DOI Link 2202
BibRef

Xu, W.[Wei], Hu, J.[Jialuo], Huang, P.P.[Ping-Ping], Tan, W.X.[Wei-Xian], Dong, Y.F.[Yi-Fan],
Processing of Multichannel Sliding Spotlight SAR Data with Large Pulse Bandwidth and Azimuth Steering Angle,
GeoRS(60), 2022, pp. 1-14.
IEEE DOI 2112
Azimuth, Bandwidth, Doppler effect, Synthetic aperture radar, Beam steering, Image reconstruction, Image resolution, sliding spotlight BibRef

Wen, Y.H.[Yu-Hao], Zhang, Z.M.[Zhi-Min], Chen, Z.[Zhen], Qiu, J.S.[Jin-Song], Ren, M.[Mingshan], Meng, X.[Xiangrui],
A Novel Time-Domain Frequency Diverse Array HRWS Imaging Scheme for Spotlight SAR,
RS(14), No. 5, 2022, pp. xx-yy.
DOI Link 2203
BibRef

Lee, H.[Haemin], Kim, K.W.[Ki-Wan],
An Integrated Raw Data Simulator for Airborne Spotlight ECCM SAR,
RS(14), No. 16, 2022, pp. xx-yy.
DOI Link 2208
BibRef

Chen, N.[Nuo], Deng, M.J.[Ming-Jun], Wang, D.[Di], Zhang, Z.P.[Zheng-Peng], Yang, Y.[Yin],
Improvement and Assessment of Gaofen-3 Spotlight Mode 3-D Localization Accuracy,
RS(15), No. 10, 2023, pp. xx-yy.
DOI Link 2306
Use for localization. BibRef

Ren, H.[Hang], Lu, Z.[Zheng], Li, G.P.[Gao-Peng], Zhang, Y.[Yun], Yang, X.Y.[Xue-Ying], Guo, Y.L.[Ya-Lin], Li, L.[Long], Qi, X.[Xin], Hua, Q.[Qinglong], Ding, C.[Chang], Mu, H.L.[Hui-Lin], Du, Y.[Yong],
A High-Resolution Spotlight Imaging Algorithm via Modified Second-Order Space-Variant Wavefront Curvature Correction for MEO/HM-BiSAR,
RS(16), No. 24, 2024, pp. 4768.
DOI Link 2501
BibRef

Wu, B.L.[Bao-Long], Liu, C.J.[Cheng-Jin], Chen, J.L.[Jian-Lai],
A Review of Spaceborne High-Resolution Spotlight/Sliding Spotlight Mode SAR Imaging,
RS(17), No. 1, 2025, pp. 38.
DOI Link 2501
BibRef

Ren, M.S.[Ming-Shan], Zhang, H.[Heng], Yu, W.D.[Wei-Dong],
High-Resolution High-Squint Large-Scene Spaceborne Sliding Spotlight SAR Processing via Joint 2D Time and Frequency Domain Resampling,
RS(17), No. 1, 2025, pp. 163.
DOI Link 2501
BibRef

Bryant, M., Gostin, L., Soumekh, M.,
Three-dimensional E-CSAR Imaging of a T-72 Tank and Synthesis of Its Spotlight, Stripmap and Interferometric SAR Reconstructions,
ICIP01(III: 628-631).
IEEE DOI 0108
BibRef

Doren, N., Jakowatz, Jr., C., Wahl, D., and Thompson, P.,
General Formulation for Wavefront Curvature Correction in Polar-Formatted Spotlight-Mode SAR Images Using Space-Variant Post-Filtering,
ICIP97(I: 861-864).
IEEE DOI BibRef 9700

Chapter on Computational Vision, Regularization, Connectionist, Morphology, Scale-Space, Perceptual Grouping, Wavelets, Color, Sensors, Optical, Laser, Radar continues in
Interferometric SAR Analysis, InSAR, IFSAR, ISAR .