New slant range model and azimuth perturbation resampling based high-squint maneuvering platform SAR imaging

doi:10.23919/JSEE.2021.000046

Journal of Systems Engineering and Electronics ›› 2021, Vol. 32 ›› Issue (3): 545-558.doi: 10.23919/JSEE.2021.000046

• ELECTRONICS TECHNOLOGY • Previous Articles Next Articles

New slant range model and azimuth perturbation resampling based high-squint maneuvering platform SAR imaging

Xuying XIONG(), Gen LI*(), Yanheng MA(), Lina CHU()

¹ Institute of UAV Engineering, Army Engingeering University, Shijiazhuang 050003, China

Received:2020-08-07 Online:2021-06-18 Published:2021-07-26
Contact: Gen LI E-mail:grabrielle@foxmail.com;radarlg@126.com;mamyh11@126.com;1052503919@qq.com
About author:|XIONG Xuying was born in 1998. She received her bachelor degree from Army Engingeering University, Shijiangzhuang, China. She is currently pursuing her M.E. degree at the Army Engingeering University. Her main research interests are radar signal processing and radar imaging with curved trajectory. E-mail: grabrielle@foxmail.com||LI Gen was born in 1991. He received his bachelor degree from Beijing Jiaotong University, Beijing, China, in 2014, and his master degree from Ordnance Engineering College, Shijiazhuang, China, in 2016. Since March 2017, he has been working toward his Ph.D. degree at the Army Engingeering University. His main research interests are synthetic aperture radar, compressed sensing, and radar imaging with curved trajectory. E-mail: radarlg@126.com||MA Yanheng was born in 1968. He received his bachelor and master degrees from National University of Defense Technology, Changsha, China, and Ph.D. degree from Xi’an Jiaotong University. He is a professor at the Army Engingeering University. His main research interests are passive detection of low, small and slow targets, testability of cognitive electronic equipment, and UAV-borne synthetic aperture radar. E-mail: mamyh11@126.com||CHU Lina was born in 1983. She received her bachelor and master degrees from China University of Petroleum (East China), Qingdao, China, in 2006 and 2009 respectively. She is a lecturer with Army Engineering University. Her main research interests are radar signal processing and UAV-borne synthetic aperture radar imaging. E-mail: 1052503919@qq.com
Supported by:
This work was supported by the basic research projects of Army Engineering University

Abstract

Abstract:

Strong spatial variance of the imaging parameters and serious geometric distortion of the image are induced by the acceleration and vertical velocity in a high-squint synthetic aperture radar (SAR) mounted on maneuvering platforms. In this paper, a frequency-domain imaging algorithm is proposed based on a novel slant range model and azimuth perturbation resampling. First, a novel slant range model is presented for mitigating the geometric distortion according to the equal squint angle curve on the ground surface. Second, the correction of azimuth-dependent range cell migration (RCM) is achieved by introducing a high-order time-domain perturbation function. Third, an azimuth perturbation resampling method is proposed for azimuth compression. The azimuth resampling and the time-domain perturbation are used for correcting first-order and high-order azimuthal spatial-variant components, respectively. Experimental results illustrate that the proposed algorithm can improve the focusing quality and the geometric distortion correction accuracy of the imaging scene effectively.

Key words: synthetic aperture radar (SAR) imaging, maneuvering platform, high-squint, azimuth perturbation resampling

Xuying XIONG, Gen LI, Yanheng MA, Lina CHU. New slant range model and azimuth perturbation resampling based high-squint maneuvering platform SAR imaging[J]. Journal of Systems Engineering and Electronics, 2021, 32(3): 545-558.

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References 23

1	ULANDER L M H, HELLSTEN H, STENSTROM G Synthetic-aperture radar processing using fast factorized back-projection. IEEE Trans. on Aerospace and Electronic Systems, 2003, 39 (3): 760- 776. doi: 10.1109/TAES.2003.1238734
2	ZHOU S, YANG L, ZHAO L F, et al Quasi-polar-based FFBP algorithm for miniature UAV SAR imaging without navigational data. IEEE Trans. on Geoscience and Remote Sensing, 2017, 55 (12): 7053- 7065. doi: 10.1109/TGRS.2017.2739133
3	LI Z Y, XING M D, XING W J, et al A modified equivalent range model and wavenumber-domain imaging approach for high-resolution-high-squint SAR with curved trajectory. IEEE Trans. on Geoscience and Remote Sensing, 2017, 55 (7): 3721- 3734. doi: 10.1109/TGRS.2017.2678763
4	CUMMING I G, WONG F H. Digital signal processing of synthetic aperture radar data: algorithms and implementation. Boston, MA: Artech House, 2005.
5	LIU G G, ZHANG L R, LIU X, et al Missile-borne large region squint SAR algorithm based on a curve trajectory. Journal of Electronics & Information Technology, 2011, 33 (3): 628- 633.
6	CHEN Y, ZHAO H C, HAN M, et al Imaging algorithm for missile-borne SAR using the fractional Fourier transform. Acta Physica Sinica, 2014, 63 (11): 358- 366.
7	DANG Y F, LIANG Y, BIE B W, et al A range perturbation approach for correcting spatially variant range envelope in diving highly squinted SAR with nonlinear trajectory. IEEE Geoscience and Remote Sensing Letters, 2018, 15 (6): 858- 862. doi: 10.1109/LGRS.2018.2812158
8	TANG S Y, ZHANG L R, GUO P, et al Processing of monostatic SAR data with general configurations. IEEE Trans. on Geoscience and Remote Sensing, 2015, 53 (12): 6529- 6546. doi: 10.1109/TGRS.2015.2443835
9	LI Z Y, LIANG Y, XING M D, et al New subaperture imaging algorithm and geometric correction method for high squint diving SAR based on equivalent squint model. Journal of Electronics & Information Technology, 2015, 37 (8): 1814- 1820.
10	LI Z Y. Study on high squint imaging algorithms for SAR mounted on maneuvering platforms. Xi’an: Xidian University, 2017. (in Chinese)
11	AN D X, CHEN L P, HUANG X T Modified nonlinear chirp scaling algorithm for one-stationary bistatic low frequency ultrawideband synthetic aperture radar imaging. Journal of Applied Remote Sensing, 2015, 9 (1): 095056. doi: 10.1117/1.JRS.9.095056
12	AN D X, HUANG X T, JIN T, et al Extended nonlinear chirp scaling algorithm for high-resolution highly squint SAR data focusing. IEEE Trans. on Geoscience and Remote Sensing, 2012, 50 (9): 3595- 3609. doi: 10.1109/TGRS.2012.2183606
13	LI D, LIN H, LIU H Q, et al Focus improvement for high-resolution highly squinted SAR imaging based on 2-D spatial-variant linear and quadratic RCMs correction and azimuth-dependent Doppler equalization. IEEE Journal of Selected Topics in Applied Earth Observations & Remote Sensing, 2017, 10 (1): 168- 183.
14	ZENG T, LI Y H, DING Z G, et al Subaperture approach based on azimuth-dependent range cell migration correction and azimuth focusing parameter equalization for maneuvering high-squint-mode SAR. IEEE Trans. on Geoscience and Remote Sensing, 2015, 53 (12): 6718- 6734. doi: 10.1109/TGRS.2015.2447393
15	LI Z Y, LIANG Y, XING M D, et al An improved range model and Omega-K-based imaging algorithm for high-squint SAR with curved trajectory and constant acceleration. IEEE Geoscience and Remote Sensing Letters, 2017, 13 (5): 656- 660.
16	LI Z Y, XING M D, LIANG Y, et al A frequency-domain imaging algorithm for highly squinted SAR mounted on maneuvering platforms with nonlinear trajectory. IEEE Trans. on Geoscience and Remote Sensing, 2016, 54 (7): 4023- 4038. doi: 10.1109/TGRS.2016.2535391
17	SUN G C, XING M D, WANG Y, et al A 2-D space-variant chirp scaling algorithm based on the RCM equalization and subband synthesis to process geosynchronous SAR data. IEEE Trans. on Geoscience and Remote Sensing, 2014, 52 (8): 4868- 4880. doi: 10.1109/TGRS.2013.2285721
18	LIAO Y, ZHOU S, YANG L Focusing of SAR with curved trajectory based on improved hyperbolic range equation. IEEE Geoscience and Remote Sensing Letters, 2018, 15 (3): 454- 458. doi: 10.1109/LGRS.2018.2794471
19	DENG H, LI Y C, LIU M Q, et al A space-variant phase filtering imaging algorithm for missile-borne BiSAR with arbitrary configuration and curved track. IEEE Sensors Journal, 2018, 18 (8): 3311- 3326. doi: 10.1109/JSEN.2018.2809508
20	ZHOU P, ZHOU S, XIONG T, et al A chirp-Z transform imaging algorithm for missile-borne SAR with diving maneuver based on the method of series reversion. Journal of Electronics & Information Technology, 2010, 32 (12): 2861- 2867.
21	LIU B C, WANG T, WU Q S, et al Bistatic SAR data focusing using an omega-K algorithm based on method of series reversion. IEEE Trans. on Geoscience and Remote Sensing, 2009, 47 (8): 2899- 2912. doi: 10.1109/TGRS.2009.2017522
22	LI D, LIAO G S, WANG W, et al Extended azimuth nonlinear chirp scaling algorithm for bistatic SAR processing in high-resolution highly squinted mode. IEEE Geoscience and Remote Sensing Letters, 2013, 11 (6): 1134- 1138.
23	BIE B W, LIANG Y, DANG Y F, et al Sub-aperture imaging algorithm for high squint SAR with curvilinear flight tracks. Systems Engineering and Electronics, 2017, 39 (3): 500- 505.

Simulation parameter	Value	Simulation parameter	Value
Carrier frequency/GHz	17	Squint angle/(°)	60
Range bandwidth/MHz	200	Platform height/km	5
Synthetic aperture time/s	2	Centre slant range/km	12
Pulse width/μs	3	Platform velocity/(m/s)	(150, 0, ?35)
Pulse repeat frequency/kHz	1	Platform acceleration/(m/s²)	(3.2, 1.2, ?0.8)

Measured parameter	Theoretical value	Target 1		Target 2		Target 3
Measured parameter	Theoretical value	Reference method	Proposed method	Reference method	Proposed method	Reference method	Proposed method
Resolution/m	0.88	2.75	0.80	0.88	0.88	1.29	0.92
PSLR/dB	?13.26	?1.36	?12.95	?13.26	?13.26	?5.03	?13.01
ISLR/dB	?9.80	?1.45	?10.15	?9.79	?9.79	?3.96	?10.06

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New slant range model and azimuth perturbation resampling based high-squint maneuvering platform SAR imaging

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