Your search keyword '"scanning radar"' showing total 26 results

1. Sparse Targets Angular Super-resolution Reconstruction Method under Unknown Antenna Pattern Errors for Scanning Radar

Author

Yin ZHANG, Ping ZHANG, Xingyu TUO, Deqing MAO, Yongchao ZHANG, Yulin HUANG, and Jianyu YANG

Subjects

scanning radar, angular super-resolution, unknown antenna pattern errors, total least squares, sparse reconstruction, Electricity and magnetism, QC501-766

Abstract

Scanning radar angular super-resolution technology is based on the relationship between the target and antenna pattern, and a deconvolution method is used to obtain angular resolution capabilities beyond the real beam. Most current angular super-resolution methods are based on ideal distortion-free antenna patterns and do not consider pattern changes in the actual process due to the influence of factors such as radar radome, antenna measurement errors, and non-ideal platform motion. In practice, an antenna pattern often has unknown errors, which can result in reduced target resolution and even false target generation. To address this problem, this paper proposes an angular super-resolution imaging method for airborne radar with unknown antenna errors. First, based on the Total Least Square (TLS) criterion, this paper considers the effect of the pattern error matrix and derive the corresponding objective function. Second, this paper employs the iterative reweighted optimization method to solve the objective function by adopting an alternative iteration solution idea. Finally, an adaptive parameter update method is introduced for algorithm hyperparameter selection. The simulation and experimental results demonstrate that the proposed method can achieve super-resolution reconstruction even in the presence of unknown antenna errors, promoting the robustness of the super-resolution algorithm.

Published

2024

2. 重尾噪声环境下的扫描雷达稳健角超分辨方法.

Author

张 寅, 张永超, 晏家楠, 刘帅迪, and 杨建宇

Abstract

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Published

2023

3. Sparse Target Batch-Processing Framework for Scanning Radar Superresolution Imaging.

Author

Tuo, Xingyu, Mao, Deqing, Zhang, Yin, Zhang, Yongchao, Huang, Yulin, and Yang, Jianyu

Abstract

Sparse superresolution algorithms have been applied in scanning radar imaging to improve its azimuth resolution. However, the inverse matrix in each iteration is usually diagonal loading by the updating result, which leads to huge computational complexity for 2-D echo data. In this letter, a batch-processing superresolution framework is proposed to process the echo data in parallel. On the one hand, the optimization problem for sparse target recovery is modified as matrix form, which presents the batch-processing potential for 2-D echo data. On the other hand, the optimization problem is solved by the proposed alternating direction method of multipliers (ADMM)-based batch-processing framework, which can avoid high-dimensional matrix inversion along different range bins. Compared with traditional sparse superresolution methods, the proposed batch-processing framework is more suitable for 2-D echo data superresolution. [ABSTRACT FROM AUTHOR]

Published

2023

4. Enhancing the Radar Cross-Range Resolution in Ultra-Fast Radar Scans by Utilizing Frequency Coded Sub-Channels.

Author

Baer, Christoph, Karsch, Nicholas, Kaesbach, Robin, and Musch, Thomas

Subjects

*RADAR, *DIRECTIONAL antennas, *SIGNAL processing, *ANTENNAS (Electronics), *VIDEO coding

Abstract

This contribution handles a single-channel radar method that utilizes frequency-coded sub-channels for enabling cross-range resolution. Because of the sub-channel coding, the whole area of interest (AOI) is scanned within a single radar measurement. To further enhance the cross-range resolution, the sub-channels' antenna beams are overlaid in this work, resulting in multiple coding signatures. Next to the operation theory, hardware components, such as coding filters and antennas, as well as signal processing methods, are presented and discussed in detail. A final measurement campaign that investigates several radar scenarios reveals high detection properties and proves the applicability of the proposed radar method. [ABSTRACT FROM AUTHOR]

Published

2022

5. Online Sparse Reconstruction for Scanning Radar Using Beam-Updating q -SPICE.

Author

Zhang, Yongchao, Li, Jie, Li, Minghui, Zhang, Yin, Luo, Jiawei, Huang, Yulin, Yang, Jianyu, and Jakobsson, Andreas

Abstract

The generalized sparse iterative covariance-based estimation ($q$ -SPICE) algorithm was recently introduced for scanning radar applications, resulting in substantial improvements in the angular resolution and quality of the processed images. Regrettably, the computational complexity and storage cost are high and quickly increase with growing data size, limiting the applicability of the estimator. In this letter, we strive to alleviate this problem, deriving a beam-updating $q$ -SPICE algorithm, allowing for efficiently updating of the sparse reconstruction result for each online radar measurement along the scanned beam. The resulting method is a regularized extension of the current online $q$ -SPICE implementation, which not only offers constant computational and storage cost, independent of the data size, but also provides enhanced robustness over the current online $q$ -SPICE. Our experimental assessment, conducted using both simulated and real data, demonstrates the advantage of the beam-updating $q$ -SPICE method in the task of sparse reconstruction for scanning radar. [ABSTRACT FROM AUTHOR]

Published

2022

6. Forward-Looking Scanning Radar Superresolution Imaging Based on Second-Order Accelerated Iterative Shrinkage-Thresholding Algorithm

Author

Wenchao Li, Meihua Niu, Yongchao Zhang, Yulin Huang, and Jianyu Yang

Subjects

Accelerated imaging, azimuth resolution, iterative shrinkage-thresholding algorithm (ISTA), scanning radar, slow convergence, Ocean engineering, TC1501-1800, Geophysics. Cosmic physics, QC801-809

Abstract

Scanning radar can be used to obtain images of targets in forward-looking area, and has attracted much attention in many fields, such as ocean monitoring, air-to-ground attack, navigation, and so on. However, its azimuth resolution is extremely poor due to the limitation of the antenna size. In order to break through the limitation, many superresolution algorithms have been proposed, and iterative shrinkage-thresholding algorithm (ISTA) is one of the most famous methods because of its antinoise ability and simplicity. In the meantime, the slow convergence of iterative shrinkage-thresholding algorithm is also known to all. In this article, a second-order accelerated ISTA for scanning radar forward-looking superresolution imaging is proposed. In this algorithm, a prediction vector is constructed before each iteration by using the first and the second-order difference information of iteration vectors to reduce the number of iterations and get a faster convergence speed. In the end, simulations and experimental results are given to illustrate the effectiveness of the accelerated imaging algorithm.

Published

2020

7. Enhancing the Radar Cross-Range Resolution in Ultra-Fast Radar Scans by Utilizing Frequency Coded Sub-Channels

Author

Christoph Baer, Nicholas Karsch, Robin Kaesbach, and Thomas Musch

Subjects

scanning radar, radar resolution, frequency coding, FMCW, Chemical technology, TP1-1185

Abstract

This contribution handles a single-channel radar method that utilizes frequency-coded sub-channels for enabling cross-range resolution. Because of the sub-channel coding, the whole area of interest (AOI) is scanned within a single radar measurement. To further enhance the cross-range resolution, the sub-channels’ antenna beams are overlaid in this work, resulting in multiple coding signatures. Next to the operation theory, hardware components, such as coding filters and antennas, as well as signal processing methods, are presented and discussed in detail. A final measurement campaign that investigates several radar scenarios reveals high detection properties and proves the applicability of the proposed radar method.

Published

2022

8. 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

9. A Sparse Denoising-Based Super-Resolution Method for Scanning Radar Imaging

Author

Qiping Zhang, Yin Zhang, Yongchao Zhang, Yulin Huang, and Jianyu Yang

Subjects

scanning radar, super-resolution, sparse, denoising, deconvolution, Science

Abstract

Scanning radar enables wide-range imaging through antenna scanning and is widely used for radar warning. The Rayleigh criterion indicates that narrow beams of radar are required to improve the azimuth resolution. However, a narrower beam means a larger antenna aperture. In practical applications, due to platform limitations, the antenna aperture is limited, resulting in a low azimuth resolution. The conventional sparse super-resolution method (SSM) has been proposed for improving the azimuth resolution of scanning radar imaging and achieving superior performance. This method uses the L1 norm to represent the sparse prior of the target and solves the L1 regularization problem to achieve super-resolution imaging under the regularization framework. The resolution of strong-point targets is improved efficiently. However, for some targets with typical shapes, the strong sparsity of the L1 norm treats them as strong-point targets, resulting in the loss of shape characteristics. Thus, we can only see the strong points in its processing results. However, in some applications that need to identify targets in detail, SSM can lead to false judgments. In this paper, a sparse denoising-based super-resolution method (SDBSM) is proposed to compensate for the deficiency of traditional SSM. The proposed SDBSM uses a sparse minimization scheme for denoising, which helps to reduce the influence of noise. Then, the super-resolution imaging is achieved by alternating iterative denoising and deconvolution. As the proposed SDBSM uses the L1 norm for denoising rather than deconvolution, the strong sparsity constraint of the L1 norm is reduced. Therefore, it can effectively preserve the shape of the target while improving the azimuth resolution. The performance of the proposed SDBSM was demonstrated via simulation and real data processing results.

Published

2021

10. Bayesian angular super-resolution for sea-surface target in forward-looking scanning radar

Author

Changlin Li, Yin Zhang, Deqing Mao, Yunlin Huang, and Jianyu Yang

Subjects

radar clutter, deconvolution, bayes methods, image sensors, iterative methods, image resolution, radar imaging, radar detection, bayesian angular super-resolution, sea-surface target, scanning radar, traditional imaging dead zone, high angular resolution, radar imaging field, imaging approaches, complex sea-surface situation, bayesian deconvolution method, target distribution, sea surface, sea-surface clutter, Engineering (General). Civil engineering (General), TA1-2040

Abstract

As the traditional imaging dead zone, how to achieve high angular resolution in forward-looking region is always a big challenge in radar imaging field. In recent years, many approaches are proposed to solve this problem. However, most of the proposed forward-looking imaging approaches fail to work in the complex sea-surface situation. In this study, a Bayesian deconvolution method aimed at the sea-surface target is presented, which relies on the convolution model between the target distribution and the antenna pattern of scanning radar. In view of the situation of sea surface, Rayleigh distribution is adopted to describe the statistical property of sea-surface clutter, and lognormal distribution is employed to represent the prior distribution of sea-surface target. Then, the optimisation theory is utilised to obtain the iterative estimated solution. The simulation results are given to verify the superior performance of the presented method.

Published

2019

11. Bayesian angular super-resolution for sea-surface target in forward-looking scanning radar.

Author

Li, Changlin, Zhang, Yin, Mao, Deqing, Huang, Yunlin, and Yang, Jianyu

Subjects

IMAGE quality analysis, RADAR target recognition, OCEAN surface topography, DECONVOLUTION (Mathematics), RAYLEIGH model, LOGNORMAL distribution

Abstract

As the traditional imaging dead zone, how to achieve high angular resolution in forward-looking region is always a big challenge in radar imaging field. In recent years, many approaches are proposed to solve this problem. However, most of the proposed forward-looking imaging approaches fail to work in the complex sea-surface situation. In this study, a Bayesian deconvolution method aimed at the sea-surface target is presented, which relies on the convolution model between the target distribution and the antenna pattern of scanning radar. In view of the situation of sea surface, Rayleigh distribution is adopted to describe the statistical property of sea-surface clutter, and lognormal distribution is employed to represent the prior distribution of sea-surface target. Then, the optimisation theory is utilised to obtain the iterative estimated solution. The simulation results are given to verify the superior performance of the presented method. [ABSTRACT FROM AUTHOR]

Published

2019

12. Wideband Sparse Reconstruction for Scanning Radar.

Author

Zhang, Yongchao, Jakobsson, Andreas, Zhang, Yin, Huang, Yulin, and Yang, Jianyu

Subjects

*COVARIANCE matrices, *SPARSE approximations, *RADAR, *MICROWAVE imaging, *RADIOMETERS

Abstract

Recently, the generalized sparse iterative covariance-based estimation algorithm was extended to allow for varying norm constraints in scanning radar applications. In this paper, further to this development, we introduce a wideband dictionary framework which can provide a computationally efficient estimation of sparse signals. The technique is formed by initially introducing a coarse grid dictionary constructed from integrating elements, spanning bands of the considered parameter space. After forming estimates of the initially activated bands, these are retained and refined, whereas nonactivated bands are discarded from the further optimization, resulting in a smaller and zoomed dictionary with a finer grid. Implementing this scheme allows for reliable sparse signal reconstruction, at a much lower computational cost as compared to directly forming a larger dictionary spanning the whole parameter space. Simulation and real data processing results demonstrate that the proposed wideband estimator offers significant computational savings, without noticeable loss of performance. [ABSTRACT FROM AUTHOR]

Published

2018

13. Super-Resolution Surface Mapping for Scanning Radar: Inverse Filtering Based on the Fast Iterative Adaptive Approach.

Author

Yongchao Zhang, Yin Zhang, Wenchao Li, Yulin Huang, and Jianyu Yang

Subjects

*TOEPLITZ operators, *SYNTHETIC aperture radar, *RADIOMETERS, *REMOTE sensing, *ELECTRONIC data processing

Abstract

High-resolution scanning radar mapping of the surface is an effective tool for addressing concerns in local environmental and social investigation fields. Regrettably, the azimuth resolution of a scanning radar is constrained by the antenna beamwidth. Multiple super-resolution approaches have been applied to the scanning radar to enhance the azimuth resolution, but they suffer from limited resolution improvement. In this paper, a methodology to derive surface estimates from the scanning radar at an improved azimuth resolution is proposed. We first consider the truncated spectrum by discarding the unreliable frequencies to suppress the noise amplification. Then, based on the iterative adaptive approach (IAA), a novel inverse filtering method is formulated to obtain lower sidelobes and a higher resolution. Finally, by taking advantage of the Fourier property of the steering matrix and the Toeplitz structure of the covariance matrix, we exploit the Gohberg-Semencul representation and the data-dependent trigonometric polynomials to derive a fast IAA (FIAA)-based inverse filtering to mitigate the computational burden. Simulation results and real data processing demonstrate that the proposed FIAA-based inverse filtering outperforms the existing super-resolution approaches in resolution improvement and results in a higher computational efficiency. [ABSTRACT FROM AUTHOR]

Published

2018

14. Range-Recursive IAA for Scanning Radar Angular Super-Resolution.

Author

Zhang, Yongchao, Jakobsson, Andreas, and Yang, Jianyu

Abstract

Recently, the iterative adaptive approach (IAA) was adopted to allow for the estimation of high-resolution scanning radar images. In this letter, we further develop this approach by introducing a range-recursive IAA (IAA-RR) formulation allowing for a computationally efficient updating of the resulting estimates along range. Besides exploiting the rich matrix structure to mitigate the computational complexity for each iteration, the correlation between adjacent range cells is exploited to accelerate the convergence of the IAA iterations. When an additional range measurement becomes available, further acceleration is available by exploiting the estimates already formed for the adjacent range cells. Compared with the existing fast IAA implementation, the proposed IAA-RR is shown to offer significant computational savings, without noticeable loss in performance. Numerical results illustrate the superior performance of the proposed IAA-RR algorithm. [ABSTRACT FROM PUBLISHER]

Published

2017

15. Forward-Looking Scanning Radar Superresolution Imaging Based on Second-Order Accelerated Iterative Shrinkage-Thresholding Algorithm

Author

Meihua Niu, Jianyu Yang, Yulin Huang, Wenchao Li, and Yongchao Zhang

Subjects

Atmospheric Science, Computer science, Geophysics. Cosmic physics, 0211 other engineering and technologies, 02 engineering and technology, law.invention, law, Convergence (routing), 0202 electrical engineering, electronic engineering, information engineering, Slow convergence, Computers in Earth Sciences, Radar, TC1501-1800, 021101 geological & geomatics engineering, Accelerated imaging, QC801-809, scanning radar, Order (ring theory), 020206 networking & telecommunications, Resolution (logic), Superresolution, Ocean engineering, Azimuth, slow convergence, iterative shrinkage-thresholding algorithm (ISTA), Antenna (radio), azimuth resolution, Algorithm

Abstract

Scanning radar can be used to obtain images of targets in forward-looking area, and has attracted much attention in many fields, such as ocean monitoring, air-to-ground attack, navigation, and so on. However, its azimuth resolution is extremely poor due to the limitation of the antenna size. In order to break through the limitation, many superresolution algorithms have been proposed, and iterative shrinkage-thresholding algorithm (ISTA) is one of the most famous methods because of its antinoise ability and simplicity. In the meantime, the slow convergence of iterative shrinkage-thresholding algorithm is also known to all. In this article, a second-order accelerated ISTA for scanning radar forward-looking superresolution imaging is proposed. In this algorithm, a prediction vector is constructed before each iteration by using the first and the second-order difference information of iteration vectors to reduce the number of iterations and get a faster convergence speed. In the end, simulations and experimental results are given to illustrate the effectiveness of the accelerated imaging algorithm.

Published

2020

16. Angular Superresolution for Scanning Radar With Improved Regularized Iterative Adaptive Approach.

Author

Zhang, Yongchao, Zhang, Yin, Huang, Yulin, Li, Wenchao, and Yang, Jianyu

Abstract

In this letter, an improved regularized iterative adaptive approach (IAA) is proposed for scanning radar angular superresolution. Because the IAA requires matrix inversion, the increasing condition number of the covariance matrix leads to the ill-posed problem of the IAA. Based on this reality, the diagonal loading method is introduced to solve the ill-posed problem. Because the loading value controls the tradeoff between the azimuth resolution and noise amplification, we use the radiometer uncertainty principle to determine the optimum loading value. When compared with the existing angular superresolution approaches, the proposed regularized IAA is shown to provide significant resolution improvement. Numerical results illustrate the superior performance of the proposed regularized IAA. [ABSTRACT FROM PUBLISHER]

Published

2016

17. A Sparse Denoising-Based Super-Resolution Method for Scanning Radar Imaging

Author

Yongchao Zhang, Qiping Zhang, Yulin Huang, Jianyu Yang, and Yin Zhang

Subjects

Computer science, sparse, Science, 0211 other engineering and technologies, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, super-resolution, 02 engineering and technology, deconvolution, Regularization (mathematics), law.invention, law, Radar imaging, 0202 electrical engineering, electronic engineering, information engineering, denoising, Radar, 021101 geological & geomatics engineering, Antenna aperture, scanning radar, Azimuth, General Earth and Planetary Sciences, Computer Science::Programming Languages, 020201 artificial intelligence & image processing, Deconvolution, Noise (video), Antenna (radio), Algorithm

Abstract

Scanning radar enables wide-range imaging through antenna scanning and is widely used for radar warning. The Rayleigh criterion indicates that narrow beams of radar are required to improve the azimuth resolution. However, a narrower beam means a larger antenna aperture. In practical applications, due to platform limitations, the antenna aperture is limited, resulting in a low azimuth resolution. The conventional sparse super-resolution method (SSM) has been proposed for improving the azimuth resolution of scanning radar imaging and achieving superior performance. This method uses the L1 norm to represent the sparse prior of the target and solves the L1 regularization problem to achieve super-resolution imaging under the regularization framework. The resolution of strong-point targets is improved efficiently. However, for some targets with typical shapes, the strong sparsity of the L1 norm treats them as strong-point targets, resulting in the loss of shape characteristics. Thus, we can only see the strong points in its processing results. However, in some applications that need to identify targets in detail, SSM can lead to false judgments. In this paper, a sparse denoising-based super-resolution method (SDBSM) is proposed to compensate for the deficiency of traditional SSM. The proposed SDBSM uses a sparse minimization scheme for denoising, which helps to reduce the influence of noise. Then, the super-resolution imaging is achieved by alternating iterative denoising and deconvolution. As the proposed SDBSM uses the L1 norm for denoising rather than deconvolution, the strong sparsity constraint of the L1 norm is reduced. Therefore, it can effectively preserve the shape of the target while improving the azimuth resolution. The performance of the proposed SDBSM was demonstrated via simulation and real data processing results.

Published

2021

18. A Fast Iterative Adaptive Approach for Scanning Radar Angular Superresolution.

Author

Zhang, Yongchao, Li, Wenchao, Zhang, Yin, Huang, Yulin, and Yang, Jianyu

Abstract

Angular superresolution technique is of great significance in enhancing the azimuth resolution when the real aperture is constrained. Recently, based on weighted least squares (WLS), the iterative adaptive approach (IAA) has been applied to scanning radar angular superresolution. The resulting estimates present noticeably superior performance compared with the existing approaches. However, the improved performance of IAA comes at the cost of high computational complexity. In this paper, a scheme of fast IAA (IAA-F) is proposed for mitigating the computational burden. First, based on the circulant structure of the steering matrix, the covariance matrix and WLS estimates are rewritten by fast convolution. Second, according to the similar block tridiagonal property between the covariance matrix and Schur complement of its submatrix, the fast matrix inversion works in an improved divide and conquer (D&C) approach, by recursively breaking down the problem of fast inversion into the same subproblem. Numerical results illustrate that the proposed IAA-F offers a time complexity reduction without loss of performance. [ABSTRACT FROM PUBLISHER]

Published

2015

19. Radar angular superresolution algorithm based on Fourier-Wavelet regularized deconvolution.

Author

Jiang, Wen, Li, Wenchao, Huang, Yulin, Liu, Zhe, Wu, Junjie, and Yang, Jianyu

Abstract

Angular resolution of real aperture radar is limited by the aperture size and wavelength. In this paper, a novel angular superresolution algorithm based on Fourier-Wavelet regularized deconvolution (ForWaRD) is proposed. Orthogonal expansion and scalar shrinkage in a tandem transform domain lie at the core of the ForWaRD. Duo to deconvolution is a noise sensitive process, the method is used to deconvolve and denoise the echo signal simultaneously. We also conclude that optimum performance of this algorithm is simultaneously determined by the Fourier structure of the antenna pattern and the wavelet structure of the surface scatterers. Simulation results show that the algorithm can efficiently enhance the resolution of scanning radar under a low SNR environment. [ABSTRACT FROM PUBLISHER]

Published

2013

20. Improving angular resolution based on maximum a posteriori criterion for scanning radar.

Author

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

Abstract

Angular resolution is crucial for scanning radar system. Angular resolution of real aperture radar (RAR) is decided by the size of the antenna aperture. In this paper, a novel method of improving angular resolution based on maximum a posteriori (MAP) framework is proposed. Firstly, scanning radar signal model is illustrated, and then an iterative deconvolution based on MAP algorithm that improves angular resolution is derived. Simulation results show that the method can efficiently improve angular resolution; then real radar experiment results validate the effectiveness of this method. [ABSTRACT FROM PUBLISHER]

Published

2012

21. Recommendations

Author

Newsome, D. H. and Newsome, D. H., editor

Published

1992

22. A shift-and-convolution technique for high-resolution radar images.

Author

Perez-Martinez, F., Garcia-Fominaya, J., and Calvo-Gallego, J.

Abstract

Theoretical and experimental results of a new method able to obtain images with high-resolution radars (HRRs) are presented in this paper. This algorithm does not need the data-phase information of the signal reflected by targets; it only uses the extracted noncoherent data. The proposed procedure works on real time, and it is compatible with the scanning and tracking radar functions. The technique consists of a modification and adaptation of algorithms used for the synchronization of the actual digital communication systems. Experimental results have been obtained with ARIES radar, a surface marine and coast surveillance HHR developed by INDRA SISTEMAS S.A. in collaboration with the Technical University of Madrid. The Spanish Ministry of Defence founded this research. [ABSTRACT FROM PUBLISHER]

Published

2005

23. Bayesian angular super-resolution for sea-surface target in forward-looking scanning radar

Author

Li Changlin, Deqing Mao, Jianyu Yang, Yin Zhang, and Yunlin Huang

Subjects

Computer science, Energy Engineering and Power Technology, image sensors, sea-surface clutter, 02 engineering and technology, deconvolution, 01 natural sciences, law.invention, Convolution, bayes methods, law, Radar imaging, Prior probability, 0202 electrical engineering, electronic engineering, information engineering, radar detection, Angular resolution, Radar, traditional imaging dead zone, complex sea-surface situation, target distribution, Rayleigh distribution, imaging approaches, 010401 analytical chemistry, scanning radar, General Engineering, radar imaging field, 020206 networking & telecommunications, 0104 chemical sciences, sea-surface target, radar imaging, bayesian deconvolution method, lcsh:TA1-2040, bayesian angular super-resolution, Clutter, iterative methods, Deconvolution, sea surface, lcsh:Engineering (General). Civil engineering (General), Algorithm, radar clutter, Software, high angular resolution, image resolution

Abstract

As the traditional imaging dead zone, how to achieve high angular resolution in forward-looking region is always a big challenge in radar imaging field. In recent years, many approaches are proposed to solve this problem. However, most of the proposed forward-looking imaging approaches fail to work in the complex sea-surface situation. In this study, a Bayesian deconvolution method aimed at the sea-surface target is presented, which relies on the convolution model between the target distribution and the antenna pattern of scanning radar. In view of the situation of sea surface, Rayleigh distribution is adopted to describe the statistical property of sea-surface clutter, and lognormal distribution is employed to represent the prior distribution of sea-surface target. Then, the optimisation theory is utilised to obtain the iterative estimated solution. The simulation results are given to verify the superior performance of the presented method.

Published

2019

24. A Sparse Denoising-Based Super-Resolution Method for Scanning Radar Imaging.

Author

Zhang, Qiping, Zhang, Yin, Zhang, Yongchao, Huang, Yulin, and Yang, Jianyu

Subjects

*RADAR, *HIGH resolution imaging, *APERTURE antennas, *IMAGE denoising, *POINT processes, *AZIMUTH, *SYNTHETIC apertures

Abstract

Scanning radar enables wide-range imaging through antenna scanning and is widely used for radar warning. The Rayleigh criterion indicates that narrow beams of radar are required to improve the azimuth resolution. However, a narrower beam means a larger antenna aperture. In practical applications, due to platform limitations, the antenna aperture is limited, resulting in a low azimuth resolution. The conventional sparse super-resolution method (SSM) has been proposed for improving the azimuth resolution of scanning radar imaging and achieving superior performance. This method uses the L 1 norm to represent the sparse prior of the target and solves the L 1 regularization problem to achieve super-resolution imaging under the regularization framework. The resolution of strong-point targets is improved efficiently. However, for some targets with typical shapes, the strong sparsity of the L 1 norm treats them as strong-point targets, resulting in the loss of shape characteristics. Thus, we can only see the strong points in its processing results. However, in some applications that need to identify targets in detail, SSM can lead to false judgments. In this paper, a sparse denoising-based super-resolution method (SDBSM) is proposed to compensate for the deficiency of traditional SSM. The proposed SDBSM uses a sparse minimization scheme for denoising, which helps to reduce the influence of noise. Then, the super-resolution imaging is achieved by alternating iterative denoising and deconvolution. As the proposed SDBSM uses the L 1 norm for denoising rather than deconvolution, the strong sparsity constraint of the L 1 norm is reduced. Therefore, it can effectively preserve the shape of the target while improving the azimuth resolution. The performance of the proposed SDBSM was demonstrated via simulation and real data processing results. [ABSTRACT FROM AUTHOR]

Published

2021

25. Traffic Data Extraction for Road Safety Improvement

Author

Somda, Flavien, Cormerais, Hervé, Institut d'Electronique et de Télécommunications de Rennes (IETR), Centre National de la Recherche Scientifique (CNRS)-Ecole Supérieure d'Electricité - SUPELEC (FRANCE)-Institut National des Sciences Appliquées - Rennes (INSA Rennes), Institut National des Sciences Appliquées (INSA)-Université de Rennes (UNIV-RENNES)-Institut National des Sciences Appliquées (INSA)-Université de Rennes (UNIV-RENNES)-Université de Rennes 1 (UR1), Université de Rennes (UNIV-RENNES), Institut d'Électronique et des Technologies du numéRique (IETR), Nantes Université (NU)-Université de Rennes 1 (UR1), Université de Rennes (UNIV-RENNES)-Université de Rennes (UNIV-RENNES)-Institut National des Sciences Appliquées - Rennes (INSA Rennes), Institut National des Sciences Appliquées (INSA)-Université de Rennes (UNIV-RENNES)-Institut National des Sciences Appliquées (INSA)-CentraleSupélec-Centre National de la Recherche Scientifique (CNRS), Université de Nantes (UN)-Université de Rennes 1 (UR1), Université de Rennes (UR)-Institut National des Sciences Appliquées - Rennes (INSA Rennes), Institut National des Sciences Appliquées (INSA)-Institut National des Sciences Appliquées (INSA)-Ecole Supérieure d'Electricité - SUPELEC (FRANCE)-Centre National de la Recherche Scientifique (CNRS), Université de Nantes (UN)-Université de Rennes (UR)-Institut National des Sciences Appliquées - Rennes (INSA Rennes), and Institut National des Sciences Appliquées (INSA)-Institut National des Sciences Appliquées (INSA)-CentraleSupélec-Centre National de la Recherche Scientifique (CNRS)

Subjects

scenarios, visibility distance, Scanning radar, Intelligent Transportation Systems, [SPI.AUTO]Engineering Sciences [physics]/Automatic

Abstract

8 pages; International audience; This paper demonstrates the benefit of scanning perception systems especially scanning radars on vehicle detection in ITS applications. Theoretical results prove that the distance of detection can be drastically improved and traffic scenarios be recognized with the use of scanning systems. Higher detection distance enables suitable anticipative actions in the vehicles control for avoiding car accidents.

Published

2009

26. An experimental microwave imaging system using pre-formed beams

Author

Sackman, George L., Electrcal Engineering, Litten, Robert Allan, Sackman, George L., Electrcal Engineering, and Litten, Robert Allan

Abstract

An experimental investigation of microwave imaging using preformed beams is made at a frequency of 24 gigahertz. The apparatus consists of a 1.5 meter diameter parabolic reflector with a mosaic of detectors at the focal plane. The detector outputs are amplified and stored to provide a set of d.c. voltages, proportional to the energy received at points in the image plane, to be applied to an intensity modulated display. Using microwave antenna and optical principles, the theory of image formation and resolution is discussed. The range capability is predicted by the radar range equation, using measured parameters. Advantages of the system, with respect to conventional scanning radar appear for fast moving objects at close range, http://archive.org/details/anexperimentalmi1094512175, Lieutenant, United States Navy, Approved for public release; distribution is unlimited.