Your search keyword '"Huang, Yulin"' showing total 82 results

1. MuA-SAR Fast Imaging Based on UCFFBP Algorithm with Multi-Level Regional Attention Strategy.

Author

Xu, Fanyun, Wang, Rufei, Huang, Yulin, Mao, Deqing, Yang, Jianyu, Zhang, Yongchao, and Zhang, Yin

Subjects

SYNTHETIC aperture radar, BISTATIC radar, SPACE-based radar, CARTESIAN coordinates, SYNTHETIC apertures, REAR-screen projection, SPATIAL systems, ALGORITHMS

Abstract

Multistatic airborne SAR (MuA-SAR) benefits from the ability to flexibly adjust the positions of multiple transmitters and receivers in space, which can shorten the synthetic aperture time to achieve the required resolution. To ensure both imaging efficiency and quality of different system spatial configurations and trajectories, the fast factorized back projection (FFBP) algorithm is proposed. However, if the FFBP algorithm based on polar coordinates is directly applied to the MuA-SAR system, the interpolation in the recursive fusion process will bring the problem of redundant calculations and error accumulation, leading to a sharp decrease in imaging efficiency and quality. In this paper, a unified Cartesian fast factorized back projection (UCFFBP) algorithm with a multi-level regional attention strategy is proposed for MuA-SAR fast imaging. First, a global Cartesian coordinate system (GCCS) is established. Through designing the rotation mapping matrix and phase compensation factor, data from different bistatic radar pairs can be processed coherently and efficiently. In addition, a multi-level regional attention strategy based on maximally stable extremal regions (MSER) is proposed. In the recursive fusion process, only the suspected target regions are paid more attention and segmented for coherent fusion at each fusion level, which further improves efficiency. The proposed UCFFBP algorithm ensures both the quality and efficiency of MuA-SAR imaging. Simulation experiments verified the effectiveness of the proposed algorithm. [ABSTRACT FROM AUTHOR]

Published

2023

2. Marginal sample discriminant embedding for SAR automatic target recognition

Author

IEEE International Radar Conference (2013: Adelaide, S.A.), Liu, Xian, Huang, Yulin, Pei, Jifang, and Yang, Jianyu

Published

2013

3. An Entropy-Awareness Meta-Learning Method for SAR Open-Set ATR.

Author

Wang, Chenwei, Luo, Siyi, Pei, Jifang, Liu, Xiaoyu, Huang, Yulin, Zhang, Yin, and Yang, Jianyu

Abstract

Existing synthetic aperture radar automatic target recognition (SAR ATR) methods have been effective for the classification of seen target classes. However, it is more meaningful and challenging to distinguish the unseen target classes, i.e., open set recognition (OSR) problem, which is an urgent problem for the practical SAR ATR. The key solution of OSR is to effectively establish the exclusiveness of feature distribution of known classes. In this letter, we propose an entropy-awareness meta-learning method that improves the exclusiveness of feature distribution of known classes which means our method is effective for not only classifying the seen classes but also encountering the unseen other classes. Through meta-learning tasks, the proposed method learns to construct a feature space of the dynamic-assigned known classes. This feature space is required by the tasks to reject all other classes not belonging to the known classes. At the same time, the proposed entropy-awareness loss helps the model to enhance the feature space with effective and robust discrimination between the known and unknown classes. Therefore, our method can construct a dynamic feature space with discrimination between the known and unknown classes to simultaneously classify the dynamic-assigned known classes and reject the unknown classes. Experiments conducted on the moving and stationary target acquisition and recognition (MSTAR) dataset have shown the effectiveness of our method for SAR OSR. [ABSTRACT FROM AUTHOR]

Published

2023

4. Kernel generalized neighbor discriminant embedding for SAR automatic target recognition

Author

Huang, Yulin, Pei, Jifang, Yang, Jianyu, Wang, Tao, Yang, Haiguang, and Wang, Bing

Published

2014

5. Semi-Supervised SAR ATR Framework with Transductive Auxiliary Segmentation.

Author

Wang, Chenwei, Liu, Xiaoyu, Huang, Yulin, Luo, Siyi, Pei, Jifang, Yang, Jianyu, and Mao, Deqing

Subjects

AUTOMATIC target recognition, SYNTHETIC aperture radar, CONVOLUTIONAL neural networks, IMAGE recognition (Computer vision), AUTOMOBILE license plates, FACE

Abstract

Convolutional neural networks (CNNs) have achieved high performance in synthetic aperture radar (SAR) automatic target recognition (ATR). However, the performance of CNNs depends heavily on a large amount of training data. The insufficiency of labeled training SAR images limits the recognition performance and even invalidates some ATR methods. Furthermore, under few labeled training data, many existing CNNs are even ineffective. To address these challenges, we propose a Semi-supervised SAR ATR Framework with transductive Auxiliary Segmentation (SFAS). The proposed framework focuses on exploiting the transductive generalization on available unlabeled samples with an auxiliary loss serving as a regularizer. Through auxiliary segmentation of unlabeled SAR samples and information residue loss (IRL) in training, the framework can employ the proposed training loop process and gradually exploit the information compilation of recognition and segmentation to construct a helpful inductive bias and achieve high performance. Experiments conducted on the MSTAR dataset have shown the effectiveness of our proposed SFAS for few-shot learning. The recognition performance of 94.18% can be achieved under 20 training samples in each class with simultaneous accurate segmentation results. Facing variances of EOCs, the recognition ratios are higher than 88.00% when 10 training samples each class. [ABSTRACT FROM AUTHOR]

Published

2022

6. Microwave Photonic SAR High-Precision Imaging Based on Optimal Subaperture Division.

Author

Hai, Yu, Li, Zhongyu, Wu, Junjie, Li, Yuting, Xiao, Yuping, Li, Wangzhe, Li, Ruoming, Wang, Bingnan, Huang, Yulin, and Yang, Jianyu

Subjects

SYNTHETIC aperture radar, SYNTHETIC apertures, IMAGING systems, MICROWAVES, MICROWAVE imaging, VIDEO compression, TIME-domain analysis

Abstract

Microwave photonic synthetic aperture radar (MWP-SAR) offers a larger signal bandwidth than conventional SAR, and its theoretical resolution can be improved to centimeter level. To achieve same order of magnitude resolution in the azimuth direction, long synthetic aperture is always required, which results in extremely high requirements for the accuracy of imaging procedure. Compared with the conventional SAR imaging algorithms, two major problems should be considered: 1) the scattering characteristics of target might vary from the frequency of signal and the angle of incidence, which seriously affects the coherence of received echo and 2) the imaging of the MWP-SAR system is more sensitive to motion errors and therefore requires higher accuracy of motion compensation processing. To solve the above issues, a high-precision imaging method for MWP-SAR is proposed. First, based on the attribute scattering center (ASC) model, this article analyzes the target scattering characteristics with different frequencies and incident angles. Then, according to the influence of scattering phase on MWP-SAR imaging, an optimal subaperture division algorithm is proposed to guarantee the coherence of each subaperture data and better imaging results. Furthermore, to compensate for the effects of high-order motion errors, this article proposes a motion error estimation algorithm based on subimage registration, where the full-aperture high-order motion errors can be divided into multiple linear components, and the flight trajectory of platform can be accurately reconstructed. Finally, a full-aperture time-domain high-precision imaging method is presented, and the effectiveness of the proposed formation is verified by both simulation and actual airborne MWP-SAR data processing. [ABSTRACT FROM AUTHOR]

Published

2022

7. Fast Sparse-TSVD Super-Resolution Method of Real Aperture Radar Forward-Looking Imaging.

Author

Tuo, Xingyu, Zhang, Yin, Huang, Yulin, and Yang, Jianyu

Subjects

SINGULAR value decomposition, AZIMUTH, HIGH resolution imaging, SIGNAL convolution, RADAR, SYNTHETIC aperture radar, SIGNAL-to-noise ratio

Abstract

Most existing super-resolution imaging methods fail to work in low signal-to-noise ratio (SNR) condition due to the ill-posed antenna measurement matrix, but the sparse-truncated singular value decomposition (TSVD) method can effectively suppress noise and improve azimuth resolution in low SNR condition. However, the current sparse-TSVD method encounters large computation cost, resulting in a slow algorithm speed. In this work, a fast sparse-TSVD super-resolution imaging method of real aperture radar is proposed. First, the proposed method is based on the results of TSVD, using the truncated unitary matrix and diagonal matrix to reconstruct the signal convolution model. The dimension of the reconstructed antenna measurement matrix reduces from $N \times N$ to $k \times N$ , and the dimension of the reconstructed echo matrix reduces from $N \times 1$ to $k \times 1$ , where $N$ is azimuth sampling points and $k$ is truncation parameter, $N \gg k$. Much of the expensive matrix– multiplication computation can then be performed on the smaller matrices, thereby accelerating the algorithm. Second, an objective function is established as the ${l_{1}}$ constraint based on the regularization strategy. Lastly, this article employs iterative reweighted least square (IRLS) method to solve the objective function, and the dimension of the reversed matrix is lessened from $N \times N$ to $k \times k$ , speeding up the algorithm further. The simulation and real data verify that the proposed algorithm not only improves the azimuth resolution in low SNR condition but also increases computational efficiency compared with the sparse-TSVD method. [ABSTRACT FROM AUTHOR]

Published

2021

8. Bistatic-Range-Doppler-Aperture Wavenumber Algorithm for Forward-Looking Spotlight SAR With Stationary Transmitter and Maneuvering Receiver.

Author

Zhang, Qianghui, Wu, Junjie, Song, Yue, Yang, Jianyu, Li, Zhongyu, and Huang, Yulin

Subjects

SYNTHETIC aperture radar, CARTESIAN coordinates, RADAR transmitters, TRANSMITTERS (Communication), COORDINATES, POLARIMETRY, ALGORITHMS, WAVENUMBER, COMPUTATIONAL complexity

Abstract

Bistatic forward-looking spotlight synthetic aperture radar with stationary transmitter and maneuvering receiver (STMR-BFSSAR) is a promising sensor for various applications, such as the automatic navigation and landing of maneuvering vehicles. Because of the bistatic forward-looking configuration and the receiver’s maneuvers, conventional image formation algorithms suffer from high computational complexity or small size of a well-focused scene if applied to STMR-BFSSAR. In this article, we propose a wavenumber-domain algorithm for STMR-BFSSAR image formation, which is termed the bistatic-range-Doppler-aperture wavenumber algorithm (BDWA). First, a novel range model in bistatic-range and Doppler-aperture coordinate space instead of conventional Cartesian coordinate space is established by employing the elliptic polar coordinate system and the method of series reversion. The novel range model not only makes the echo’s samples to be regular along the direction of the bistatic-range wavenumber axis but also constructs a curved wavefront close to the true wavefront. Second, an operation termed wavenumber-domain gridding is conceived to regularize the echo’s samples along the Doppler-aperture wavenumber axis, which can be implemented by 1-D interpolation. The proposed algorithm significantly outperforms the conventional algorithms in terms of computational complexity and scene size limits. Both point and distributed targets are simulated for two STMR-BFSSAR systems with different parameters. The simulation results verify the validity and superiority of the proposed BDWA. [ABSTRACT FROM AUTHOR]

Published

2021

9. Simultaneous Super-Resolution and Target Detection of Forward-Looking Scanning Radar via Low-Rank and Sparsity Constrained Method.

Author

Li, Wenchao, Zhang, Wentao, Zhang, Qiping, Zhang, Yin, Huang, Yulin, and Yang, Jianyu

Subjects

SYNTHETIC aperture radar, SYNTHETIC apertures, HIGH resolution imaging, RADAR, LOW-rank matrices, RESCUE work, ALGORITHMS

Abstract

Forward-looking imaging and target detection are highly desirable in many military and civilian fields, such as search and rescue, sea surface surveillance, airport surveillance, and guidance. However, there is a blind zone of forward-looking imaging for conventional Doppler beam sharpening and synthetic aperture radar. Scanning radar can be utilized to obtain a real beam image of a forward-looking area and implement target detection, while its azimuth resolution is poor due to the limitation of antenna size. Besides, during the processing procedure, imaging and target detection are usually regarded as two independent parts, which means that the imaging result will directly affect the detection performance. In this article, an integrated algorithm of super-resolution imaging and target detection for forward-looking scanning radar is proposed. In this algorithm, first of all, low-rank and sparse constraints as regularization norms are incorporated into the forward-looking scanning radar imaging and the objective function is established. Subsequently, the convex theory is utilized to solve the objective function and transform the problem of simultaneous super-resolution imaging and target detection into an optimization problem. Lastly, the super-resolution imaging and the target detection results are obtained simultaneously by solving the optimization problem using the alternating direction method of multipliers. In addition, simulation and experiment results are given to verify the effectiveness of the proposed algorithm. [ABSTRACT FROM AUTHOR]

Published

2020

10. TV-Sparse Super-Resolution Method for Radar Forward-Looking Imaging.

Author

Zhang, Qiping, Zhang, Yin, Huang, Yulin, Zhang, Yongchao, Pei, Jifang, Yi, Qingying, Li, Wenchao, and Yang, Jianyu

Subjects

HIGH resolution imaging, RADAR, ALGORITHMS, DIGITAL video, SYNTHETIC aperture radar

Abstract

Real-aperture radar can be utilized to realize forward-looking imaging by antenna scanning the imaging region. However, low azimuth resolution seriously affects its practical application. Although traditional super-resolution methods could enhance azimuth resolution to a certain extent, effective preservation of contour information for important targets still remains to be a problem. In this article, a method of total variation-sparse (TV-sparse) multiconstraint deconvolution is proposed to improve azimuth resolution of forward-looking imaging as well as preserve contour information of important targets. Since our interested targets usually appear to be sparse, the sparse constraint of the target is introduced first to achieve high resolution of forward-looking images, which may cause the loss of target contour information in the meantime. Second, total variation (TV) constraint is introduced based on the sparse constraint, converting traditional single-constraint super-resolution problem to a multiconstraint problem. We then use the split Bregman algorithm (SBA) to solve the multiconstraint problem, whose solution is the super-resolution image of radar forward-looking region. Compared with traditional super-resolution methods, the proposed method can improve the azimuth resolution of radar forward-looking imaging as well as better restore target contour information by adjusting respective weights of sparse constraint and TV constraint. Finally, the performance of the proposed method is validated with the simulation and measured data. [ABSTRACT FROM AUTHOR]

Published

2020

11. Video SAR Imaging Based on Low-Rank Tensor Recovery.

Author

Pu, Wei, Wang, Xiaodong, Wu, Junjie, Huang, Yulin, and Yang, Jianyu

Subjects

SYNTHETIC aperture radar, COMPRESSED sensing, IMAGE processing, VIDEOS

Abstract

Due to its ability of forming continuous images for a ground scene of interest, the video synthetic aperture radar (SAR) has been studied in recent years. However, as video SAR needs to reconstruct many frames, the data are of enormous amount and the imaging process is of large computational cost, which limits its applications. In this article, we exploit the redundancy property of multiframe video SAR data, which can be modeled as low-rank tensor, and formulate the video SAR imaging process as a low-rank tensor recovery problem, which is solved by an efficient alternating minimization method. We empirically compare the proposed method with several state-of-the-art video SAR imaging algorithms, including the fast back-projection (FBP) method and the compressed sensing (CS)-based method. Experiments on both simulated and real data show that the proposed low-rank tensor-based method requires significantly less amount of data samples while achieving similar or better imaging performance. [ABSTRACT FROM AUTHOR]

Published

2021

12. Three-step ground moving target detection method for bistatic forward-looking SAR.

Author

Liu, Zhutian, Li, Zhongyu, Yang, Qing, Wu, Junjie, Huang, Yulin, and Yang, Jianyu

Subjects

DOPPLER radar, SYNTHETIC aperture radar, IMAGING systems, HIGH resolution imaging, SIGNAL-to-noise ratio

Abstract

Detecting ground moving target in bistatic forward-looking synthetic aperture radar (BFSAR) has become increasingly important in military and civil field. Compared with pulse Doppler radar, the long observation time and high resolution of BFSAR will lead to three problems in the received signal: Doppler ambiguity, large range cell migration and Doppler cell migration, which tremendously aggravate the difficulty of ground moving target detection (GMTD). In this study, the authors propose a three-step ground moving target detection method for BFSAR to solve these problems and achieve good performance on GMTD. First, the bulk-deramp filtering and Keystone transform are exploited to suppress Doppler ambiguity and correct range cell migration, respectively. Then, time-division space–time adaptive processing is utilised for clutter suppression, which eliminates the effect of the Doppler cell migration. Finally, modified Wigner–Ville distribution method is applied to further improve the signal to clutter and noise ratio and the moving target can be detected in the integration domain. Simulations are carried out to demonstrate the effectiveness of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2019

13. Fast Factorized Backprojection Imaging Algorithm Integrated With Motion Trajectory Estimation for Bistatic Forward-Looking SAR.

Author

Pu, Wei, Wu, Junjie, Huang, Yulin, Yang, Jianyu, and Yang, Haiguang

Abstract

A bistatic forward-looking synthetic aperture radar (BFSAR) is increasingly in the focus of study, as it breaks through the limitations of imaging on a forward-looking terrain of a moving platform. Fast factorized backprojection (FFBP) is a reliable BFSAR imaging algorithm, with both imaging precision and efficiency being taken into consideration. In FFBP imaging, compensation of the motion errors is important to obtain a well-focused image. To accomplish an accurate motion compensation in image processing, a high-precision navigation system is needed. However, in many cases, because of the accuracy limit of such systems, motion errors are difficult to be compensated correctly, resulting chiefly in resolution decrease in the final images. To deal with such a problem, we propose an FFBP imaging algorithm integrated with motion trajectory estimation for BFSAR. First, a coarse-to-fine residual range cell migration (RCM) correction scheme is applied to ensure the residual RCM within a range resolution. Then, an optimization model with respect to motion trajectory estimation under the criterion of maximum image sharpness is built during FFBP imaging. According to the coarse-to-fine residual RCM correction scheme and the motion trajectory estimation model, a block coordinate descent technique based on steepest descent optimization method integrated with residual RCM correction is proposed to estimate the motion errors in FFBP imaging. We empirically compare the proposed method with several state-of-the-art BFSAR imaging and autofocus algorithms. Simulations on BFSAR data show that the proposed method is more accurate and has similar computational cost. [ABSTRACT FROM AUTHOR]

Published

2019

14. PFA for Bistatic Forward-Looking SAR Mounted on High-Speed Maneuvering Platforms.

Author

Zhang, Qianghui, Wu, Junjie, Li, Zhongyu, Miao, Yuxuan, Huang, Yulin, and Yang, Jianyu

Subjects

SYNTHETIC aperture radar, IMPLICIT functions, STRUCTURE-activity relationships, CURVATURE, CLUTTER (Radar), CONTINUOUS time models

Abstract

Being capable of providing weather-independent, day-and-night, forward-looking, and high-resolution images, bistatic forward-looking synthetic aperture radar (BFSAR) is a promising sensing technique in applications such as the scene-matching-aided navigation for recently emerging high-speed maneuvering platforms (HMPs). Because of the high speed and the great maneuverability of HMPs and the bistatic forward-looking configuration, conventional image formation algorithms, such as polar format algorithm (PFA), are no longer suitable for HMP-borne BFSAR (HMP-BFSAR). Hence, in this paper, we propose a novel PFA for HMP-BFSAR image formation. In the proposed PFA, a range model, termed as quasi-continuous -move range model, is established by taking the maneuvers of the receiver during pulse propagation into account instead of adopting stop-and-go approximation. Moreover, to take advantage of the collected $k$ -set efficiently, an affine mapping, termed as $k$ -set affine mapping, is conceived to transform the parallelogram-shaped $k$ -set support region to a horizontal and quasi-rectangular one. Furthermore, to compensate for the defocus effect induced by wavefront curvature, a closed-form refocus filter based on the implicit function theorem is derived. Both point target simulation and distributed target simulation are presented in this paper. The simulation results show that the proposed PFA significantly outperforms the conventional PFA in terms of focusing quality and computational efficiency when applied to HMP-BFSAR image formation. [ABSTRACT FROM AUTHOR]

Published

2019

15. Echo Model Without Stop-and-Go Approximation for Bistatic SAR With Maneuvers.

Author

Zhang, Qianghui, Wu, Junjie, Qu, Jingyi, Li, Zhongyu, Huang, Yulin, and Yang, Jianyu

Abstract

An echo model plays a pivotal role in the processing of synthetic aperture radar (SAR) data. It has been shown that the widely adopted echo models based on stop-and-go approximation (SAG) are unsuitable for use in many emerging radar systems with high resolution or high-speed platforms. More accurate echo models without SAG have been proposed for some special monostatic scenarios, such as low-Earth-orbit SAR and geosynchronous SAR. However, due to their inherent assumptions, such as linear and constant-speed/orbit-based motion, these conventional echo models cannot be applied to general cases, which involve bistatic configurations and maneuvers. Maneuvers or nonlinear/inconstant-speed motion are very common in cases, such as circular SAR and maneuvering-platform-borne SAR. In this letter, we propose a generalized echo model for bistatic SAR, which accounts for maneuvers of the platforms during pulse propagation. Moreover, we obtain a high-precision closed-form expression of the model by approximating high-order terms of the accurate range history of the receiver. Compared with the conventional models, the proposed echo model can be applied to a much greater number of cases, ranging from slow and constant-speed platforms to fast and maneuvering platforms. Theoretical analysis and backprojection-based image formation simulations confirm the validity of the proposed echo model. [ABSTRACT FROM AUTHOR]

Published

2019

16. Airborne Forward-Looking Radar Super-Resolution Imaging Using Iterative Adaptive Approach.

Author

Zhang, Yongchao, Mao, Deqing, Zhang, Qian, Zhang, Yin, Huang, Yulin, and Yang, Jianyu

Abstract

Airborne forward-looking radar (AFLR) imaging has raised many concerns in fields of Earth observation, independent of weather and daytime. Constrained by imaging principles, conventional high-resolution radar imaging techniques such as synthetic aperture radar (SAR) and Doppler beam sharpening (DBS) are incapable of AFLR imaging. The real aperture radar (RAR) can obtain AFLR images using a scanning antenna, but suffers from coarse cross-range resolution. Recently, there has been much attention paid to the iterative adaptive approach (IAA), which draws from the benefits of RAR imaging and provides improved cross-range resolution. However, earlier work on the IAA imposed a convolution model on the received azimuth echo, neglecting the effect of the Doppler phase. This model mismatch degrades the imaging performance for moving platforms. To settle this problem, this paper first establishes a Doppler-convolution model of AFLR imaging, where both Doppler phase and antenna convolution effects are considered, allowing more accurate reconstruction when applying the IAA to formulate a super-resolution image. Then, a data-depended approach for Doppler centroid estimation is proposed to circumvent the problem of low estimation precision using platform motion parameters delivered by navigational devices mounted on the radar platform. Simulation results demonstrate that the proposed implementation of the IAA based on the Doppler-convolution model and Doppler centroid estimation can overcome the deficiencies of the SAR and DBS techniques in the forward-looking imaging direction, and present a noticeably superior performance as compared with conventional AFLR imaging methods. [ABSTRACT FROM AUTHOR]

Published

2019

17. Joint Sparsity-Based Imaging and Motion Error Estimation for BFSAR.

Author

Pu, Wei, Wu, Junjie, Wang, Xiaodong, Huang, Yulin, Zha, Yuebo, and Yang, Jianyu

Subjects

SYNTHETIC aperture radar, BISTATIC radar, ERROR analysis in mathematics, ESTIMATION theory, IMAGE processing

Abstract

Due to its flexibility and low cost, the bistatic forward-looking synthetic aperture radar (BFSAR) which employs side-looking transmitter and forward-looking receiver has been studied in recent years. Sparsity-based techniques have been applied in the field of BFSAR imaging and show great potential. In sparsity-based BFSAR imaging, compensation of the motion errors is crucial to get a well-focused image. For fields that admit a sparse representation, we propose a sparsity-based imaging approach integrated with motion error estimation and compensation in this paper. First, a novel joint phase-amplitude compensation-based motion error correction scheme is developed to cope with the spatial variance of motion error. Then, an inversion observation model of the range-Doppler algorithm combined with motion error correction is derived, based on which a joint problem of BFSAR imaging and motion error estimation is formulated as a sparse recovery problem and solved in an iterative way, where in each iteration, both image formation and motion error correction are carried out. Experiments on both the simulated and real BFSAR data show that the proposed method can obtain a more accurate estimation result, and generate better focused images compared with the existing methods. [ABSTRACT FROM AUTHOR]

Published

2019

18. Multiview Synthetic Aperture Radar Automatic Target Recognition Optimization: Modeling and Implementation.

Author

Pei, Jifang, Huang, Yulin, Sun, Zhichao, Zhang, Yin, Yang, Jianyu, and Yeo, Tat-Soon

Subjects

*SYNTHETIC aperture radar, *AUTOMATIC target recognition, *GENETIC algorithms, *DETECTORS, *IMAGING systems

Abstract

Multiview synthetic aperture radar (SAR) images could provide much richer information for automatic target recognition (ATR) than from a single-view image. It is desirable to find optimal SAR platform flight paths and acquire a sequence of SAR images from appropriate views, so that multiview SAR ATR can be carried out accurately and efficiently. In this paper, a novel optimization framework for multiview SAR ATR is proposed and implemented. The geometry of the multiview SAR ATR is modeled according to the recognition mission and flight environment. Then, the multiview SAR ATR is abstracted and transformed into a constrained multiobjective optimization problem with objective functions considering the tradeoffs between recognition performance and efficiency and security. A specific approach based on convolutional neural network ensemble and constrained nondominated sorting genetic algorithm II is employed to solve the multiobjective optimization, and optimal flight paths and corresponding imaging viewpoints are obtained. The SAR sensor can thus choose an applicable flight path to acquire the multiview SAR images from different tradeoff solutions according to application requirements. Finally, accurate recognition results can be obtained based on those multiview SAR images. Extensive experiments have shown the validity and superiority of the proposed optimization framework of multiview SAR ATR. [ABSTRACT FROM AUTHOR]

Published

2018

19. Topology Design for Geosynchronous Spaceborne–Airborne Multistatic SAR.

Author

An, Hongyang, Wu, Junjie, Sun, Zhichao, Yang, Jianyu, Huang, Yulin, and Yang, Haiguang

Abstract

Geosynchronous (GEO) spaceborne–airborne multistatic synthetic aperture radar (GEO MulSAR) is more flexible and accessible in remote sensing applications because of the high-altitude illuminator and the separation of the receivers and transmitter. In addition, the information obtained by the multiple airborne receivers can be fused to enhance the spatial resolution. However, the fused spatial resolution severely depends on the applied multistatic topology. To achieve the optimal fused spatial resolution by properly adjusting the imaging topology, a topology design method is proposed in this letter. First, the spatial resolution model of GEO MulSAR is given, and the dependence of the spatial resolution on the multistatic topology is analyzed in detail. Then, a topology design method is proposed to obtain the best multistatic topology that simultaneously optimizes the resolution cell area and resolution disequilibrium factor. Finally, the simulation results validate the effectiveness of the proposed method, and some insights into designing the multistatic topology are given. [ABSTRACT FROM AUTHOR]

Published

2018

20. Nonsystematic Range Cell Migration Analysis and Autofocus Correction for Bistatic Forward-looking SAR.

Author

Pu, Wei, Wu, Junjie, Huang, Yulin, Wang, Xiaodong, Yang, Jianyu, Li, Wenchao, and Yang, Haiguang

Subjects

BISTATIC radar, SYNTHETIC aperture radar, ORDINARY differential equations, AZIMUTH, IMAGING systems

Abstract

In general, autofocus methods integrated with frequency-domain imaging algorithms are instrumental to obtain a well-focused bistatic forward-looking synthetic aperture radar (BFSAR) image in the presence of motion errors. Nevertheless, before applying autofocus methods to correct the azimuth phase errors, range cell migration (RCM) should be eliminated by the RCM correction (RCMC) procedure in frequency-domain imaging algorithms. With motion errors being taken into account, there always exists some residual nonsystematic RCM (NsRCM), which refers to the residual migration components after the RCMC procedure. For the conventional side-looking SAR, NsRCM is caused by motion errors. On the other hand, NsRCM of BFSAR is originated from motion errors before RCMC and the NsRCM amplified by the RCMC procedure. In this paper, we analyze the different types of NsRCM in BFSAR imaging and their relationship. Based on the analyses, we propose an autofocus NsRCM correction scheme for BFSAR imagery using frequency-domain imaging algorithms that can eliminate the range-dependent NsRCM. The proposed scheme consists of three steps. First, for the BFSAR data after range compression and RCMC, a division procedure is carried out in the azimuth direction. The subblocks with the highest signal-to-clutter ratio along the range direction are selected after the azimuth segmentation procedure. Second, for the selected subblocks, the total NsRCM is estimated based on the minimum-entropy criterion. Based on the estimation results, different parts of the NsRCM are obtained by solving an ordinary differential equation. Third, a two-step compensation of the NsRCM is executed to reach the spatially variant correction. Simulations and experimental results are provided to demonstrate that our proposed scheme is effective for BFSAR imaging. [ABSTRACT FROM AUTHOR]

Published

2018

21. Bistatic Forward-Looking SAR Focusing Using$\omega\hbox{--}k$Based on Spectrum Modeling and Optimization.

Author

Wu, Junjie, Pu, Wei, Huang, Yulin, Yang, Jianyu, and Yang, Haiguang

Abstract

Bistatic synthetic aperture radar (SAR) is able to break through the limitation of monostatic SAR on forward-looking area imaging with appropriate geometry configurations. Thanks to such an ability, bistatic forward-looking SAR (BFSAR) has extensive potential practical applications. For the focusing problem of conventional side-looking SAR, $\omega\hbox{--}k$ algorithm is accepted as the ideal solution. In this paper, the $\omega\hbox{--}k$ algorithm will be discussed in BFSAR geometry. As for the bistatic configuration, spatial domain linearization procedure should be carried out to extract a range variable from the point target reference spectrum (PTRS) in the existing $\omega\hbox{--}k$ algorithms. With respect to the BFSAR geometry, nevertheless, the linearization procedure reduces the accuracy of PTRS seriously. To cope with such a problem, a novel $\omega\hbox{--}k$ algorithm for BFSAR is proposed. In the proposed method, the range variable is modeled as a parameterized polynomial, and the corresponding PTRS with respect to two-dimensional frequencies is established. Then, the parameters are estimated by differential evolution to minimize the PTRS errors for each range coordinate and frequency point. Based on the estimated PTRS, the BFSAR data can be focused well by the proposed $\omega\hbox{--}k$ algorithm. Simulation results verify the effectiveness of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2018

22. An Optimal 2-D Spectrum Matching Method for SAR Ground Moving Target Imaging.

Author

Li, Zhongyu, Wu, Junjie, Liu, Zhutian, Huang, Yulin, Yang, Haiguang, and Yang, Jianyu

Subjects

SYNTHETIC aperture radar, DIFFERENTIAL evolution, MOVING target indicator radar, MATHEMATICAL optimization, VELOCITY

Abstract

In synthetic aperture radar (SAR) imagery, images of ground moving targets (GMTs) are smeared, distorted, and shifted. Current GMT imaging methods are mostly based on range-Doppler algorithms, which have two main drawbacks: 1) coupling between range cell migration correction (RCMC) and Doppler parameter estimation and 2) cross terms degrade the performance of the nonlinear estimation methods. In this paper, an optimal 2-D spectrum matching method for SAR GMT imaging is proposed. The main innovation or advantage of this method is that the GMT imaging problem is transformed into a constrained optimization problem, and differential evolution is applied to guarantee a high-processing efficiency. As they are associated with the Doppler centroid variation compensation and range shift compensation processing, all GMT point scatterers can be well focused and well located. Compared with the current methods, the improvements exhibited by this method include three main benefits: 1) RCMC and Doppler parameter estimation can be simultaneously accomplished; 2) both along- and cross-track GMT velocities can be simultaneously estimated; and 3) this method can be applied to both monostatic and bistatic SARs. Numerical simulations and experimental data processing have verified the effectiveness and robustness of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2018

23. SAR Automatic Target Recognition Based on Multiview Deep Learning Framework.

Author

Pei, Jifang, Huang, Yulin, Huo, Weibo, Zhang, Yin, Yang, Jianyu, and Yeo, Tat-Soon

Subjects

*SYNTHETIC aperture radar, *AUTOMATIC target recognition, *DEEP learning, *ARTIFICIAL neural networks, *IMAGE recognition (Computer vision)

Abstract

It is a feasible and promising way to utilize deep neural networks to learn and extract valuable features from synthetic aperture radar (SAR) images for SAR automatic target recognition (ATR). However, it is too difficult to effectively train the deep neural networks with limited raw SAR images. In this paper, we propose a new approach to do SAR ATR, in which a multiview deep learning framework was employed. Based on the multiview SAR ATR pattern, we first present a flexible mean to generate adequate multiview SAR data, which can guarantee a large amount of inputs for network training without needing many raw SAR images. Then, a unique deep convolutional neural network containing a parallel network topology with multiple inputs is adopted. The features of input SAR images from different views will be learned by the proposed network layer by layer; meanwhile, the learned features from the distinct views are fused in different layers progressively. Therefore, the proposed framework is able to achieve a superior recognition performance, and requires only a small number of raw SAR images for network training samples generation. Experimental results have shown the superiority of the proposed framework based on the Moving and Stationary Target Acquisition and Recognition data set. [ABSTRACT FROM AUTHOR]

Published

2018

24. A deramping based omega-k algorithm for wide scene spotlight SAR

Author

Wu Junjie, Teng Long, Huang Yulin, and Yang Jianyu

Subjects

Synthetic aperture radar, business.industry, Computer science, Doppler radar, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, law.invention, symbols.namesake, Fourier transform, law, Radar imaging, symbols, Bandwidth (computing), Computer vision, Algorithm design, Artificial intelligence, Point target, business, Image resolution, Algorithm, Interpolation

Abstract

Spotlight SAR accumulates large Doppler bandwidth to improve azimuth resolution. On condition of certain pulse reputation frequency (PRF), Doppler bandwidth accumulates at the cost of imaging scene. This is a classic tradeoff between azimuth resolution and scene size in spotlight mode. A novel algorithm is proposed here to break the restriction. Firstly, a deramping based method is presented through bulk data processing to finish azimuth Fourier transform under low PRF. Omega-k algorithm is then applied to focus the full image. This algorithm is free of classic restriction and requires PRF only larger than the instantaneous bandwidth. Its bulk data processing is efficiency with no sub-aperture or interpolation. In this case, this algorithm is qualified to wide scene spotlight SAR imaging. The effectiveness of this algorithm is demonstrated by point target simulation.

Published

2012

25. New approach for improving Mutual Information in POLSAR image registration

Author

Xuan Yanyan, Yang Jianyu, and Huang Yulin

Subjects

Synthetic aperture radar, Covariance matrix, Computer science, business.industry, fungi, Image registration, Pattern recognition, Mutual information, Similarity measure, Measure (mathematics), body regions, Computer Science::Graphics, Signal-to-noise ratio, Similarity (network science), Radar imaging, Computer vision, Artificial intelligence, skin and connective tissue diseases, business

Abstract

Aiming at the problem that information source of similarity measure is limited to image intensity usually in multi-polarization SAR registration, we propose an improved Mutual Information(MI) based on the multiple correlation information between the same polarized channels (HH, W) in multi-polarization SAR images. In this method, by analyzing the correlation characteristics of three polarized channels in multi-polarization SAR, and using channel correlation information extracted from polarimetric covariance matrix, we compute MI in multi-polarization SAR to improve the similarity measure. Finally, the simulation results show that, in the multi-polarization SAR image registration, similarity measure information sources affect the performance of similarity measure. We compare the similarity measures with different information sources in curve sharpness and noise immunity. The results prove that the measure based on the correlation of the same polarized channels for multi-polarization SAR performs excellently.

Published

2010

26. SAR Doppler frequency rate estimation based on time-frequency rate distribution

Author

Huang-yulin, Xiong-Jintao, Liu-Xianhua, Wu-junjie, Wang-Pu, and Yang-Jianyu

Subjects

Synthetic aperture radar, Pulse-Doppler radar, Acoustics, Doppler radar, Instantaneous phase, law.invention, Continuous-wave radar, Inverse synthetic aperture radar, symbols.namesake, law, Radar imaging, symbols, Doppler effect, Remote sensing, Mathematics

Abstract

Time-frequency rate distribution (TFRD) indicates the characteristics of instantaneous frequency rate (IFR) of a signal. This paper proposed a method based on time-frequency rate distribution to estimate Doppler frequency rate by analyzing the linear frequency-modulated (LFM) characteristics of synthetic aperture radar (SAR) echo in the azimuth direction. This method can be applied to low signal-to-noise ratio (SNR) situation with high estimation precision. Simulation and practical results show the effectiveness of the method.

Published

2009

27. Research on airborne bistatic SAR squint imaging mode algorithm and experiment data processing

Author

Xiong Jin-tao, Yang Jianyu, Xian Li, and Huang Yulin

Subjects

Synthetic aperture radar, Inverse synthetic aperture radar, Continuous-wave radar, Bistatic radar, Radar engineering details, Computer science, Radar imaging, Side looking airborne radar, Algorithm, Remote sensing, Passive radar

Abstract

The parallel flight squint mode of airborne bistatic synthetic aperture radar (SAR) is discussed in this paper. The bistatic squint imaging mode (SIM) algorithm is used to solve the coupling between the range and the azimuth of this mode. Simulation results prove the availability of this algorithm. The bistatic SIM algorithm is also used to process the experiment data, and a well focused Bistatic SAR image is generated successfully. Comparing the generated image with the bistatic rang-Doppler (RD) algorithm, we can find that the result of bistatic SIM algorithm is much better than that of bistatic RD algorithm in the parallel flight squint mode.

Published

2007

28. Vehicleborne bistatic synthetic aperture radar imaging

Author

Huang Yulin, Yang Haiguang, Tian Zhong, Xian Li, and Yang Jianyu

Subjects

Synthetic aperture radar, business.industry, Computer science, Echo (computing), ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Side looking airborne radar, Phase synchronization, Constant false alarm rate, Inverse synthetic aperture radar, Bistatic radar, Radar imaging, Synchronization (computer science), Computer vision, Artificial intelligence, business

Abstract

A complete vehicleborne Bistatic Synthetic Aperture Radar (SAR) imaging experiment is presented in this paper. Some new technologies were used to solve synchronization problems. An algorithm named the Glide Window Echo CFAR was used to realize time synchronization and collect the echo. High stable local oscillator was employed to achieve frequency and phase synchronization, and the PRF was adjusted adaptively in the Data Acquisition Device in the receive station. Finally, the Range-Doppler algorithm with range migration correction was using to image the certain scene successfully.

Published

2007

29. Research on A novel fast backprojection algorithm for stripmap bistatic SAR imaging

Author

Xiong Jin-tao, Huang Yulin, Chen Juan, and Yang Jiangyu

Subjects

Synthetic aperture radar, Computer science, business.industry, Passive radar, Continuous-wave radar, Inverse synthetic aperture radar, Bistatic radar, Radar engineering details, Robustness (computer science), Radar imaging, Computer vision, Artificial intelligence, business, Algorithm

Abstract

In this paper, a novel fast backprojection (BP) algorithm for stripmap bistatic SAR is presented. This algorithm gets improvements from the perspective of beam form and the space relation between the flight path and the mapping areas. Comparing with the traditional BP algorithm, the fast BP algorithm has higher computational efficiency. Also, it keeps the advantages of the traditional BP algorithm, such as robustness, high imaging precision, small memory requirements in processor and parallel processing easily. The imaging results of point targets and the experimental data verify the advantages of the fast BP algorithm.

Published

2007

30. Analysis of Bistatic SAR Frequencey Synchronization

Author

Huang Yulin, Liu Rui, and Xiong Jin-tao

Subjects

Synthetic aperture radar, Computer science, fungi, Synchronization, Passive radar, body regions, Continuous-wave radar, Inverse synthetic aperture radar, Bistatic radar, Radar engineering details, Radar imaging, Electronic engineering, skin and connective tissue diseases, Algorithm

Abstract

In this paper, a bistatic SAR echo's mathematical expression with frequency errors is given, and the frequency error was analysed. Two types of frequency synchronization errors were considered. We analysed the different effects about imaging of bistatic SAR in the condition that the echo with different frequency errors. The analytical result is proved by simulation, it can be the reference for bistatic SAR system design.

Published

2006

31. A Rise-Dimensional Modeling and Estimation Method for Flight Trajectory Error in Bistatic Forward-Looking SAR.

Author

Pu, Wei, Wu, Junjie, Huang, Yulin, Du, Ke, Li, Wenchao, Yang, Jianyu, and Yang, Haiguang

Abstract

Bistatic forward-looking synthetic aperture radar (BFSAR) is a kind of bistatic SAR system that can image forward-looking terrain in the flight direction of a moving platform. In BFSAR, compensation of the flight trajectory errors is of great significance to get a well-focused image. To accomplish an accurate motion compensation in image processing, a high-precision navigation system is needed. However, in many cases, due to the accuracy limit of such systems, flight trajectory errors are hard to be compensated correctly, causing mainly the resolution decrease in final images. In order to cope with such a problem, we propose a rise-dimensional modeling and estimation for flight trajectory error based on raw BFSAR data in this paper. To apply this method, we first carry out a preprocessing named azimuth-slowtime decoupling to deal with the spatially variant flight trajectory error before estimation. Then, an optimization model for flight trajectory estimation under the criterion of maximum image intensity is built. The solution to the optimization model is the accurate flight trajectory. Then, block coordinate descent technique is used to solve this optimization model. The processing of BFSAR data shows that the algorithm can obtain a more accurate estimation results, and generate better focused images compared with the existing trajectory estimation method. [ABSTRACT FROM PUBLISHER]

Published

2017

32. An Azimuth-Variant Autofocus Scheme of Bistatic Forward-Looking Synthetic Aperture Radar.

Author

Pu, Wei, Li, Wenchao, Wu, Junjie, Huang, Yulin, Yang, Jianyu, and Yang, Haiguang

Abstract

In bistatic forward-looking synthetic aperture radar (BFSAR), conventional autofocus algorithms cannot estimate the phase errors accurately when the range walk is compensated in the azimuthal time domain. This problem stems from the influence of the azimuth-variant Doppler coefficients after linear range cell migration correction in azimuthal time domain. In principle, nonlinear chirp scaling processing can be carried out to remove the azimuth variance. Nevertheless, Doppler azimuth variations of the Doppler parameters induced by the motion errors are not taken into consideration and serious defocus would emerge in the final image. To cope with such a problem, an estimation–evaluation–equalization scheme is proposed before conventional autofocus for BFSAR. Different from the conventional autofocus method, the azimuth-variant Doppler coefficients are additionally estimated and equalized before autofocus, and as a consequence, phase errors can be precisely estimated. The BFSAR data processing results demonstrate the validity of the proposed method on the improvement of autofocus in BFSAR. [ABSTRACT FROM PUBLISHER]

Published

2017

33. Motion Errors and Compensation for Bistatic Forward-Looking SAR With Cubic-Order Processing.

Author

Pu, Wei, Wu, Junjie, Huang, Yulin, Li, Wenchao, Sun, Zhichao, Yang, Jianyu, and Yang, Haiguang

Subjects

SYNTHETIC aperture radar, MOTION compensation (Signal processing), IMAGING systems, REMOTE sensing, GEOLOGY

Abstract

With appropriate geometry configurations, bistatic synthetic aperture radar (SAR) can break through the limitations of monostatic SAR on forward-looking imaging. Owing to such a capability, bistatic forward-looking SAR (BFSAR) has extensive potential applications. In BFSAR, the compensation of the spatially variant motion errors is of great significance to get a well-focused image. In this paper, first, the spatial-variance properties of motion errors are analyzed analytically and quantitatively. Different from the side-looking monostatic and bistatic SAR, 2-D space-variant motion errors should be taken into consideration in BFSAR. The 2-D spatial variance of the motion errors can be categorized into two parts, range-variant motion errors of the transmitter and azimuth-variant motion errors of the receiver. Moreover, these two parts are independent of each other. Based on this property analysis, second, a motion compensation (MoCo) approach with cubic-order processing is proposed to deal with the spatially variant motion errors in BFSAR. In the cubic-order processing, the first-order MoCo is performed to correct the spatially independent motion errors on the raw data. The second-order MoCo is accomplished on the non-range-cell-migration (RCM) data to deal with the range-variant errors. After the second-order MoCo, since the signal direction of the non-RCM data coincides with the variant direction of the uncompensated phase errors, the azimuth-variant motion errors and slow time signal are coupled together. To cope with such a problem, the slow time signal is transformed into the direction perpendicular to the azimuth by a novel procedure named azimuth–slow time decoupling. At this stage, the coupling between the azimuth-variant motion errors and slow time signal has been eliminated. Azimuth-variant motion errors can be corrected precisely. Simulation and experimental results verify the effectiveness of the proposed method. [ABSTRACT FROM PUBLISHER]

Published

2016

34. Path Planning for GEO-UAV Bistatic SAR Using Constrained Adaptive Multiobjective Differential Evolution.

Author

Sun, Zhichao, Wu, Junjie, Yang, Jianyu, Huang, Yulin, Li, Caipin, and Li, Dongtao

Subjects

SYNTHETIC aperture radar, DRONE aircraft, MATHEMATICAL optimization, DIFFERENTIAL signal detection, SPATIAL analysis (Statistics)

Abstract

With the geosynchronous synthetic aperture radar (SAR) satellite as the transmitter, the unmanned aerial vehicle (UAV) can passively receive the echo within the illuminated ground area and achieve 2-D imaging of the interested target. This SAR system, known as GEO-UAV bistatic SAR, is capable of autonomously accomplishing the bistatic SAR mission in rough terrain environments by prespecifying a path for the UAV receiver. In this paper, the GEO-UAV bistatic SAR system is first investigated. The practical advantages and spatial resolution are then analyzed in detail. The spatial resolution of GEO-UAV bistatic SAR is dependent on the observation geometry, which is determined by the UAV path. Therefore, the path planning for GEO-UAV bistatic SAR aims at identifying a set of optimal paths for the UAV receiver to travel through a 3-D terrain environment that simultaneously guarantees the safety of the UAV and achieves SAR imaging with optimized performance during the flight. The path planning is modeled as a constrained multiobjective optimization problem (MOP), which accurately represents the two main aspects for the path planning problem, i.e., UAV navigation and bistatic SAR imaging. Then, a path planning method based on a constrained-adaptive-multiobjective-differential-evolution algorithm is proposed to solve the MOP and generate multiple feasible paths for the UAV receiver with different tradeoffs between navigation for UAV and bistatic SAR imaging performance. The GEO-UAV bistatic SAR mission designer can choose a path from the solution set according to the application requirements, which makes the method more pragmatic. [ABSTRACT FROM PUBLISHER]

Published

2016

35. A residual range cell migration correction algorithm for bistatic forward-looking SAR.

Author

Pu, Wei, Huang, Yulin, Wu, Junjie, Yang, Jianyu, and Li, Wenchao

Subjects

SYNTHETIC aperture radar, AZIMUTH, SIMULATION methods & models

Abstract

For bistatic forward-looking synthetic aperture radar (BFSAR), images are often blurred by uncompensated radar motion errors. To get refocused images, autofocus is a useful postprocessing technique. However, a severe drawback of the autofocus algorithms is that they are only capable of removing one-dimensional azimuth phase errors. In BFSAR, motion errors and approximations of imaging algorithms introduce residual range cell migration (RCM) on BFSAR data as well. When residual RCM is within a range resolution cell, it can be neglected. However, the residual migration, which exceeds a range cell, is increasingly encountered as resolution becomes finer and finer. A novel residual RCM correction method is proposed in this paper. By fitting the low-frequency phase difference of adjacent azimuth cells, residual RCM of each azimuth cell can be corrected precisely and effectively. Simulations and real data experiments are carried out to validate the effectiveness of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2016

36. Ground-Moving Target Imaging and Velocity Estimation Based on Mismatched Compression for Bistatic Forward-Looking SAR.

Author

Li, Zhongyu, Wu, Junjie, Huang, Yulin, Sun, Zhichao, and Yang, Jianyu

Subjects

SYNTHETIC aperture radar, IMAGING systems, DATA compression, DOPPLER effect, COMPUTER simulation

Abstract

Bistatic forward-looking synthetic aperture radar (BFL-SAR) is a kind of bistatic SAR system that can image forward-looking terrain in the flight direction of an aircraft. Until now, BFL-SAR imaging theories and methods have been researched for stationary targets. Unlike the stationary target, the motion of a ground-moving target (GMT) induces unknown range cell migration and additional modulation of the azimuth signal. Thus, to finely image the GMT, one must obtain its velocity parameters accurately, but they are usually unknown. In this paper, a novel GMT imaging and velocity estimation method, which is based on mismatched compression, is proposed for BFL-SAR without a priori knowledge of the GMT's velocity parameters. The main idea behind mismatched compression is to use a presumed azimuth reference function for performing correlated operation with the azimuth signal of the GMT. In general, the Doppler parameters of the presumed azimuth reference function are different from those of the GMT's azimuth signal because the velocity parameters of the GMT are unknown. Therefore, the correlation operation referred to earlier is actually mismatched compression, and the resulting image is shifted and defocused. The shifted and defocused image is utilized to get the real Doppler and velocity parameters of the GMT. The advantage of this method is that not only the GMT can be well focused but also the GMT's velocity can be simultaneously obtained. In addition, this method needs only monochannel antenna. The proposed BFL-SAR GMT imaging and velocity estimation method is validated by numerical simulations. [ABSTRACT FROM AUTHOR]

Published

2016

37. SAR Imagery Feature Extraction Using 2DPCA-Based Two-Dimensional Neighborhood Virtual Points Discriminant Embedding.

Author

Pei, Jifang, Huang, Yulin, Huo, Weibo, Wu, Junjie, Yang, Jianyu, and Yang, Haiguang

Abstract

Synthetic aperture radar (SAR) is an important microwave sensor that is capable of high-resolution imaging. Extracting valuable features from the SAR target imagery is one of crucial issues in SAR automatic target recognition (ATR). In this paper, we propose a new feature extraction method named 2-D principal-component-analysis-based 2-D neighborhood virtual points discriminant embedding (2DPCA-based 2DNVPDE) for SAR ATR. The SAR imagery is projected into the feature space by 2DPCA and 2DNVPDE in this approach. 2DPCA is able to preserve the global spatial structure of the original imagery, while 2DNVPDE establishes the spatial relationships of the neighborhoods to find the classification information from the neighborhoods of the samples. Hence, our method can extract powerful recognition information and represent the original image in low dimensions. Based on the MSTAR dataset, the experimental results show that the proposed method is able to achieve a higher recognition rate with a lower feature dimension over some existing SAR imagery feature extraction methods. Besides, it indicates that our method has a significant advantage in recognition performance and a lower sensitivity in statistical standpoint. [ABSTRACT FROM PUBLISHER]

Published

2016

38. Inclined Geosynchronous Spaceborne–Airborne Bistatic SAR: Performance Analysis and Mission Design.

Author

Sun, Zhichao, Wu, Junjie, Pei, Jifang, Li, Zhongyu, Huang, Yulin, and Yang, Jianyu

Subjects

SYNTHETIC aperture radar, SIGNAL-to-noise ratio, CHRISTIAN missions, BISTATIC radar, REMOTE sensing by radar

Abstract

Geosynchronous synthetic aperture radar (GEO-SAR) offers new opportunities for continuous Earth observation missions with large coverage and short revisit cycle. The unique features of GEO-SAR present huge potentials for bistatic observation applications. In this paper, the concept and advantages of GEO bistatic SAR (GEO-BiSAR) are first investigated. The system consists of a GEO illuminator and an airborne receiver, such as an airplane or a near-space vehicle. Compared with a monostatic GEO-SAR system, the bistatic configuration can provide finer spatial resolution and higher signal-to-noise ration (SNR) with less system complexity. The spatial resolution characteristics are then analyzed based on generalized ambiguity function, where the time-varying GEO velocity, Earth rotation, and ellipsoid Earth surface are taken into consideration. Meanwhile, the bistatic SNR is analyzed using the integration equation model. In this paper, the mission design for GEO-BiSAR aims at identifying a set of receiver flight parameters and bistatic configurations to obtain the desired spatial resolution and SNR. Based on the desired imaging performance of a specific application background, the mission design process is modeled as a nonlinear equation system (NES). Finally, a mission design method based on fast nondominated sorting genetic algorithm is proposed to solve the NES and obtain multiple optimal solutions to guide the receiver flight missions. Examples of the mission design process are given to validate the effectiveness of the proposed method. The results of the mission design can be conveniently used to guide the receiver flight mission for the desired imaging performance, which is highly desirable in practical applications. [ABSTRACT FROM AUTHOR]

Published

2016

39. Bistatic forward-looking SAR ground moving target detection and imaging.

Author

Li, Zhongyu, Wu, Junjie, Yi, Qingying, Huang, Yulin, Yang, Jianyu, and Bao, Yi

Subjects

SYNTHETIC aperture radar, MOVING target indicator radar, SIGNALS & signaling, DOPPLER effect, COMPUTER simulation

Abstract

Bistatic forward-looking synthetic aperture radar (BFSAR) is a kind of bistatic SAR (BiSAR) system that can image the forward-looking terrain in the flight direction of a receiver. Current literature and reports about BFSAR imaging are mainly concentrated on stationary scene imaging. In this paper, the ground moving target (GMT) theories for BFSAR are discussed. Firstly, the BFSAR signal models of a general GMT in both time-domain and Doppler-domain are shown. Meanwhile, the echo characteristics of the GMT are analyzed, which include the migration characteristic, the Doppler characteristic, the coupling characteristic, etc. After the above analysis, a GMT detection and imaging method for BFSAR is presented. The main purpose of the GMT detection method is to find out the difference between the GMT and the stationary background in an appropriate domain. However, for BFSAR, it is hard to do this since the relative movements between the BFSAR sensors and the GMT are strongly coupled, i.e., their respective influences cannot be easily separated. Different from the existing detection methods which use Doppler frequency (Doppler centroid) in Doppler-domain or space-time characteristics in space-time domain to differentiate the GMT from stationary background, the main idea of the method proposed in this paper is to distinguish the GMT from stationary background by their different Doppler frequency rates (DFRs) in DFR-domain. However, in order to do this, the stationary background?s DFRs must be equalized and the GMT?s DFR should be distinct from the same DFR of the stationary background. Then, the product second-order ambiguity function (PSAF) is used to detect and focus the GMT. Numerical simulations and experimental data processing verify the validity of the GMT theories and the method shown in this paper. [ABSTRACT FROM AUTHOR]

Published

2015

40. Highly Squint SAR Data Focusing Based on Keystone Transform and Azimuth Extended Nonlinear Chirp Scaling.

Author

Sun, Zhichao, Wu, Junjie, Li, Zhongyu, Huang, Yulin, and Yang, Jianyu

Abstract

Highly squint synthetic aperture radar (SAR) data focusing is a more challenging and difficult task than the side-looking SAR due to the strong 2-D coupling of echo signal induced by the imaging mode. Although several algorithms have been proposed, they fail to take into consideration the spatial variance of linear range cell migration (RCM). Moreover, the RCM correction (RCMC) process in range frequency and azimuth time domain by phase multiplication brings the problem of azimuth variation of the Doppler centroid, which has a great influence on the azimuth focusing. In this letter, an algorithm based on keystone transform (KT) and azimuth extended nonlinear chirp scaling (ENLCS) is derived to deal with these problems. A new method for higher order RCMC is derived to remove the residual RCM after KT. Then, azimuth ENLCS is performed to equalize the azimuth-variant Doppler centroid and FM rate. The simulation results verify the effectiveness of this algorithm. [ABSTRACT FROM PUBLISHER]

Published

2015

41. Sample Discriminant Analysis for SAR ATR.

Author

Liu, Xian, Huang, Yulin, Pei, Jifang, and Yang, Jianyu

Abstract

Feature extraction is a key step in synthetic-aperture-radar automatic target recognition. In this letter, we propose a novel feature extraction method named sample discriminant analysis (SDA) that is based on the manifold learning theory. The method directly extracts features from 2-D image matrices rather than vectors. Furthermore, SDA preserves the neighborhood information of the original data in dimension reduction. It also makes within-class samples closer and makes between-class samples father away in a low-dimensional space. Meanwhile, a sample discriminant coefficient is employed in the method to give each sample a weight related to its location and similarity to neighboring samples. Thus, the discriminative ability of the method is improved. Experimental results based on the moving and stationary target acquisition and recognition database show that the proposed method can improve recognition performance. [ABSTRACT FROM PUBLISHER]

Published

2014

42. An Omega-k Imaging Algorithm for Translational Variant Bistatic SAR Based on Linearization Theory.

Author

Li, Zhongyu, Wu, Junjie, Yi, Qingying, Huang, Yulin, and Yang, Jianyu

Abstract

Doppler parameters, range cell migrations (RCMs), and higher order coupling terms in the raw data of translational variant bistatic synthetic aperture radar (TV-BiSAR) exhibit 2-D spatial variations. The 2-D spatial variations result in significant performance degradation of TV-BiSAR imaging. To solve these problems, an Omega- k imaging algorithm based on linearization theory is proposed in this letter. Compared with the traditional Omega-k algorithm that uses the 1-D Stolt transformation to eliminate only the spatial variations in the range direction, the proposed algorithm applies the 2-D Stolt transformations to achieve the goal of both 2-D frequency linearization and 2-D spatial-domain linearization. After the 2-D Stolt transformations, a focused image can be obtained by performing a 2-D inverse fast Fourier transform (IFFT). In the proposed Omega-k imaging algorithm, the 2-D spatial variations of the Doppler parameters, RCM, and higher order coupling terms for TV-BiSAR can be simultaneously eliminated. However, in previous publications about BiSAR imaging algorithms, the spatial variations in the azimuth direction are barely considered, which reduces the imaging accuracy. Numerical simulations verify the effectiveness of the proposed method. [ABSTRACT FROM PUBLISHER]

Published

2014

43. Improved Doppler parameter estimation of squint SAR based on slope detection.

Author

Li, Wenchao, Yang, Jianyu, and Huang, Yulin

Subjects

SYNTHETIC aperture radar, COMPUTER simulation, PARAMETER estimation, SLOPES (Physical geography), DATA analysis, RADON transforms

Abstract

For high-quality synthetic aperture radar (SAR) processing, Doppler parameter estimation is an essential procedure. In this article, first the relationship between slope and Doppler parameter of squint SAR is established, and then an improved slope-detection-based Doppler parameter estimation scheme is proposed. In the scheme, the intensity data are first converted into binary data by setting a threshold using the Ostu algorithm, and then a Radon transform is conducted on the binary data in two steps: the coarse and fine Radon transform. Using the proposed scheme, the binary data will have sparse features, and the number and interval of search for the Radon transform can be greatly reduced. Hence, the Doppler parameter can be estimated with more speed than conventional Radon-transform-based methods. Besides, Doppler centroid and Doppler rate can be estimated with the same scene. Simulations and experiments with real data validate the effectiveness of the scheme. [ABSTRACT FROM AUTHOR]

Published

2014

44. Neighborhood Geometric Center Scaling Embedding for SAR ATR.

Author

Huang, Yulin, Peia, Jifang, Yanga, Jianyu, Wang, Bing, and Liu, Xian

Subjects

*IMAGE quality in synthetic aperture radar, *AUTOMATIC target recognition, *FEATURE extraction, *SYNTHETIC aperture radar, *DIMENSION reduction (Statistics), *SCALING laws (Statistical physics)

Abstract

Feature extraction from high-dimensional synthetic aperture radar images is one of the key steps for SAR automatic target recognition. In this paper, we propose a new approach to SAR image feature extraction that is named neighborhood geometric center scaling embedding, which is based on manifold learning theory. In our framework, neighborhood geometric center scaling is introduced to construct neighborhood relationships. The samples are endowed with clear clustering directions in dimensionality reduction, and the classification is better conducted in the feature space than in the original space. Moreover, by introducing neighborhood geometric center scaling, the influence of neighbor parameters on recognition performance is reduced effectively. The experiment based on the Moving and Stationary Target Acquisition and Recognition database shows that the proposed method has better recognition performance and higher stability than other methods. [ABSTRACT FROM PUBLISHER]

Published

2014

45. Omega-K Imaging Algorithm for One-Stationary Bistatic SAR.

Author

Wu, Junjie, Li, Zhongyu, Huang, Yulin, Yang, Jianyu, and Liu, Qing Huo

Subjects

SYNTHETIC aperture radar, AZIMUTH, IMAGING systems, ALGORITHMS (Physics), FREQUENCY spectra, ELECTRONIC linearization, COMPUTER simulation

Abstract

In bistatic synthetic aperture radar (BSAR) with one-stationary station, azimuth variation is a major problem. In this paper, based on the two-dimensional (2D) spatial linearization of the accurate analytical point target reference spectrum, an Omega-K imaging algorithm to deal with this problem is proposed. Different from the traditional Omega-K algorithms for monostatic SAR and translational invariant BSAR, the approach uses a 2D Stolt frequency transformation. In addition, a compensation method for the phase error caused by the linearization and the related geometry registration are also discussed. Numerical simulations verify the effectiveness of the proposed method. [ABSTRACT FROM PUBLISHER]

Published

2014

46. A Geometry-Based Doppler Centroid Estimator for Bistatic Forward-Looking SAR.

Author

Li, Wenchao, Yang, Jianyu, Huang, Yulin, and Wu, Junjie

Abstract

For high-quality synthetic aperture radar (SAR) processing, Doppler centroid estimation is an essential procedure. An incorrect Doppler centroid would cause a loss of signal-to-noise ratio, an increase in the azimuth ambiguity level, and a shift in the location of the target. Based on the analysis of the range migration characteristic of the transmitter-fixed bistatic forward-looking SAR, a geometry-based Doppler centroid estimator is proposed in this letter. By searching for the range walk slope based on the minimum entropy, this method estimates the unambiguous Doppler centroid directly. Simulations validate the effectiveness of this method. [ABSTRACT FROM PUBLISHER]

Published

2012

47. Variable-aperture-bp-based near space slow speed SAR imaging.

Author

Yang, Jianyu, Li, Wenchao, Huang, Yulin, Yang, Haiguang, Yuan, Ye, and Song, Leiquan

Abstract

Pulse repetition frequency (PRF) redundancy exists in near space slow speed SAR due to slow speed motion, and then the beam can point to different scene at the same position. Hence, the large scene imaging can be realized. However, the range migration and azimuth resolution is azimuth variant, which makes the imaging difficult. In this paper, imaging mode of near space slow speed SAR is presented, and the variable aperture BP imaging algorithm is proposed. Simulations are given to verify the effectiveness of the imaging scheme. [ABSTRACT FROM PUBLISHER]

Published

2013

48. FEF-Net: A Deep Learning Approach to Multiview SAR Image Target Recognition.

Author

Pei, Jifang, Wang, Zhiyong, Sun, Xueping, Huo, Weibo, Zhang, Yin, Huang, Yulin, Wu, Junjie, and Yang, Jianyu

Subjects

IMAGE recognition (Computer vision), DEEP learning, AUTOMATIC target recognition, SYNTHETIC aperture radar, MICROWAVE imaging, FEATURE extraction

Abstract

Synthetic aperture radar (SAR) is an advanced microwave imaging system of great importance. The recognition of real-world targets from SAR images, i.e., automatic target recognition (ATR), is an attractive but challenging issue. The majority of existing SAR ATR methods are designed for single-view SAR images. However, multiview SAR images contain more abundant classification information than single-view SAR images, which benefits automatic target classification and recognition. This paper proposes an end-to-end deep feature extraction and fusion network (FEF-Net) that can effectively exploit recognition information from multiview SAR images and can boost the target recognition performance. The proposed FEF-Net is based on a multiple-input network structure with some distinct and useful learning modules, such as deformable convolution and squeeze-and-excitation (SE). Multiview recognition information can be effectively extracted and fused with these modules. Therefore, excellent multiview SAR target recognition performance can be achieved by the proposed FEF-Net. The superiority of the proposed FEF-Net was validated based on experiments with the moving and stationary target acquisition and recognition (MSTAR) dataset. [ABSTRACT FROM AUTHOR]

Published

2021

49. Multiview Deep Feature Learning Network for SAR Automatic Target Recognition.

Author

Pei, Jifang, Huo, Weibo, Wang, Chenwei, Huang, Yulin, Zhang, Yin, Wu, Junjie, Yang, Jianyu, and Pia, Addabbo

Subjects

AUTOMATIC target recognition, DEEP learning, SYNTHETIC aperture radar, SYSTEMS design, LEARNING modules

Abstract

Multiview synthetic aperture radar (SAR) images contain much richer information for automatic target recognition (ATR) than a single-view one. It is desirable to establish a reasonable multiview ATR scheme and design effective ATR algorithm to thoroughly learn and extract that classification information, so that superior SAR ATR performance can be achieved. Hence, a general processing framework applicable for a multiview SAR ATR pattern is first given in this paper, which can provide an effective approach to ATR system design. Then, a new ATR method using a multiview deep feature learning network is designed based on the proposed multiview ATR framework. The proposed neural network is with a multiple input parallel topology and some distinct deep feature learning modules, with which significant classification features, the intra-view and inter-view features existing in the input multiview SAR images, will be learned simultaneously and thoroughly. Therefore, the proposed multiview deep feature learning network can achieve an excellent SAR ATR performance. Experimental results have shown the superiorities of the proposed multiview SAR ATR method under various operating conditions. [ABSTRACT FROM AUTHOR]

Published

2021

50. When Deep Learning Meets Multi-Task Learning in SAR ATR: Simultaneous Target Recognition and Segmentation.

Author

Wang, Chenwei, Pei, Jifang, Wang, Zhiyong, Huang, Yulin, Wu, Junjie, Yang, Haiguang, and Yang, Jianyu

Subjects

DEEP learning, AUTOMATIC target recognition, SYNTHETIC aperture radar, TARGET acquisition, REMOTE sensing

Abstract

With the recent advances of deep learning, automatic target recognition (ATR) of synthetic aperture radar (SAR) has achieved superior performance. By not being limited to the target category, the SAR ATR system could benefit from the simultaneous extraction of multifarious target attributes. In this paper, we propose a new multi-task learning approach for SAR ATR, which could obtain the accurate category and precise shape of the targets simultaneously. By introducing deep learning theory into multi-task learning, we first propose a novel multi-task deep learning framework with two main structures: encoder and decoder. The encoder is constructed to extract sufficient image features in different scales for the decoder, while the decoder is a tasks-specific structure which employs these extracted features adaptively and optimally to meet the different feature demands of the recognition and segmentation. Therefore, the proposed framework has the ability to achieve superior recognition and segmentation performance. Based on the Moving and Stationary Target Acquisition and Recognition (MSTAR) dataset, experimental results show the superiority of the proposed framework in terms of recognition and segmentation. [ABSTRACT FROM AUTHOR]

Published

2020