Your search keyword '"Tan, Weixian"' showing total 119 results

1. Enhancing concealed object detection in Active Millimeter Wave Images using wavelet transform

Author

Su, Yun, Tan, Weixian, Dong, Yifan, Xu, Wei, Huang, Pingping, Zhang, Jianxin, and Zhang, Diankun

Published

2024

2. A voltage coordination control strategy based on the reactive power-active network loss partitioned aggregation domain

Author

Wang, Zhenhao, Tan, Weixian, Li, He, Ge, Jinming, and Wang, Wei

Published

2023

3. A Two-Component Polarimetric Target Decomposition Algorithm with Grassland Application.

Author

Huang, Pingping, Chen, Yalan, Li, Xiujuan, Tan, Weixian, Chen, Yuejuan, Yang, Xiangli, Dong, Yifan, Lv, Xiaoqi, and Li, Baoyu

Subjects

PLANT anatomy, GRASSLAND plants, REMOTE sensing, GRASSLANDS, ANALYTICAL solutions

Abstract

The study of the polarimetric target decomposition algorithm with physical scattering models has contributed to the development of the field of remote sensing because of its simple and clear physical meaning with a small computational effort. However, most of the volume scattering models in these algorithms are for forests or crops, and there is a lack of volume scattering models for grasslands. In order to improve the accuracy of the polarimetric target decomposition algorithm adapted to grassland data, in this paper, a novel volume scattering model is derived considering the characteristics of real grassland plant structure and combined with the backward scattering coefficients of grass, which is abstracted as a rotatable ellipsoid of variable shape. In the process of rotation, the possibility of rotation is considered in two dimensions, the tilt angle and canting angle; for particle shape, the anisotropy degree A is directly introduced as a parameter to describe and expand the applicability of the model at the same time. After obtaining the analytical solution of the parameters and using the principle of least negative power to determine the optimal solution of the model, the algorithm is validated by applying it to the C-band AirBorne dataset of Hunshandak grassland in Inner Mongolia and the X-band Cosmos-Skymed dataset of Xiwuqi grassland in Inner Mongolia. The performance of the algorithm with five polarimetric target decomposition algorithms is studied comparatively. The experimental results show that the algorithm proposed in this paper outperforms the other algorithms in terms of grassland decomposition accuracy on different bands of data. [ABSTRACT FROM AUTHOR]

Published

2024

4. Research on the Application of Dynamic Process Correlation Based on Radar Data in Mine Slope Sliding Early Warning.

Author

Chen, Yuejuan, Liu, Yang, Qi, Yaolong, Huang, Pingping, Tan, Weixian, Yin, Bo, Li, Xiujuan, Li, Xianglei, and Zhao, Dejun

Subjects

PHASE noise, COAL mining, TIME series analysis, STANDARD deviations, LANDSLIDES

Abstract

With the gradual expansion of mining scale in open-pit coal mines, slope safety problems are increasingly diversified and complicated. In order to reduce the potential loss caused by slope sliding and reduce the major threat to the safety of life and property of residents in the mining area, this study selected two mining areas in Xinjiang as cases and focused on the relationship between phase noise and deformation. The study predicts the specific time point of slope sliding by analyzing the dynamic history correlation tangent angle between the two. Firstly, the time series data of the micro-variation monitoring radar are used to obtain the small deformation of the study area by differential InSAR (D-InSAR), and the phase noise is extracted from the radar echo in the sequence data. Then, the volume of the deformation body is calculated by analyzing the small deformation at each time point, and the standard deviation of the phase noise is calculated accordingly. Finally, the sliding time of the deformation body is predicted by combining the tangent angle of the ratio of the volume of the deformation body to the standard deviation of the phase noise. The results show that the maximum deformation rates of the deformation bodies in the studied mining areas reach 10.1 mm/h and 6.65 mm/h, respectively, and the maximum deformation volumes are 2,619,521.74 mm3 and 2,503,794.206 mm3, respectively. The predicted landslide time is earlier than the actual landslide time, which verifies the effectiveness of the proposed method. This prediction method can effectively identify the upcoming sliding events and the characteristics of the slope, provide more accurate and reliable prediction results for the slope monitoring staff, and significantly improve the efficiency of slope monitoring and early warning. [ABSTRACT FROM AUTHOR]

Published

2024

5. Phase Noise Compensation Algorithm for Space-Borne Azimuth Multi-Channel SAR.

Author

Bai, Lu, Xu, Wei, Huang, Pingping, Tan, Weixian, Qi, Yaolong, Chen, Yuejuan, and Gao, Zhiqi

Subjects

PHASE noise, AZIMUTH, ECHO, SYNTHETIC aperture radar, COST functions, RANDOM noise theory, ALGORITHMS

Abstract

Azimuth multi-channel synthetic aperture radar (SAR) has always been an important technical means to achieve high-resolution wide-swath (HRWS) SAR imaging. However, in the space-borne azimuth multi-channel SAR system, random phase noise will be produced during the operation of each channel receiver. The phase noise of each channel is superimposed on the SAR echo signal of the corresponding channel, which will cause the phase imbalance between the channels and lead to the generation of false targets. In view of the above problems, this paper proposes a random phase noise compensation method for space-borne azimuth multi-channel SAR. This method performs feature decomposition by calculating the covariance matrix of the echo signal and converts the random phase noise estimation into the optimal solution of the cost function. Considering that the phase noise in the receiver has frequency-dependent and time-varying characteristics, this method calculates the phase noise estimation value corresponding to each range-frequency point in the range direction and obtains the phase noise estimation value by expectation in the azimuth direction. The proposed random phase noise compensation method can suppress false targets well and make the radar present a well-focused SAR image. Finally, the usefulness of the suggested method is verified by simulation experiments. [ABSTRACT FROM AUTHOR]

Published

2024

6. A Clustering Approach for Atmospheric Phase Error Correction in Ground-Based SAR Using Spatial Autocorrelation.

Author

Qi, Yaolong, Hui, Jiaxin, Hou, Ting, Huang, Pingping, Tan, Weixian, and Xu, Wei

Subjects

SYNTHETIC aperture radar, ELECTROMAGNETIC wave propagation, SPACE-based radar, SUCCESSIVE approximation analog-to-digital converters, WEATHER, AUTOCORRELATION (Statistics), BLOCK codes

Abstract

When using ground-based synthetic aperture radar (GB-SAR) for monitoring open-pit mines, dynamic atmospheric conditions can interfere with the propagation speed of electromagnetic waves, resulting in atmospheric phase errors. These errors are particularly complex in rapidly changing weather conditions or steep terrain, significantly impacting monitoring accuracy. In such scenarios, traditional regression model-based atmospheric phase correction (APC) methods often become unsuitable. To address this issue, this paper proposes a clustering method based on the spatial autocorrelation function. First, the interferogram is uniformly divided into multiple blocks, and the phase consistency of each block is evaluated using the spatial autocorrelation function. Then, a region growing algorithm is employed to classify each block according to its phase pattern, followed by merging adjacent blocks based on statistical data. To verify the feasibility of the proposed method, both the traditional regression model-based method and the proposed method were applied to deformation monitoring of an open-pit mine in Northwest China. The experimental results show that for complex atmospheric phase scenarios, the proposed method significantly outperformed traditional methods, demonstrating its superiority. [ABSTRACT FROM AUTHOR]

Published

2024

7. MSSD-Net: Multi-Scale SAR Ship Detection Network.

Author

Wang, Xi, Xu, Wei, Huang, Pingping, and Tan, Weixian

Subjects

SYNTHETIC aperture radar, SHIP traffic control, PROCESS capability, ARTIFICIAL satellites, FEATURE extraction

Abstract

In recent years, the development of neural networks has significantly advanced their application in Synthetic Aperture Radar (SAR) ship target detection for maritime traffic control and ship management. However, traditional neural network architectures are often complex and resource intensive, making them unsuitable for deployment on artificial satellites. To address this issue, this paper proposes a lightweight neural network: the Multi-Scale SAR Ship Detection Network (MSSD-Net). Initially, the MobileOne network module is employed to construct the backbone network for feature extraction from SAR images. Subsequently, a Multi-Scale Coordinate Attention (MSCA) module is designed to enhance the network's capability to process contextual information. This is followed by the integration of features across different scales using an FPN + PAN structure. Lastly, an Anchor-Free approach is utilized for the rapid detection of ship targets. To evaluate the performance of MSSD-Net, we conducted extensive experiments on the Synthetic Aperture Radar Ship Detection Dataset (SSDD) and SAR-Ship-Dataset. Our experimental results demonstrate that MSSD-Net achieves a mean average precision (mAP) of 98.02% on the SSDD while maintaining a compact model size of only 1.635 million parameters. This indicates that MSSD-Net effectively reduces model complexity without compromising its ability to achieve high accuracy in object detection tasks. [ABSTRACT FROM AUTHOR]

Published

2024

8. Airborne Radar Space–Time Adaptive Processing Algorithm Based on Dictionary and Clutter Power Spectrum Correction.

Author

Gao, Zhiqi, Deng, Wei, Huang, Pingping, Xu, Wei, and Tan, Weixian

Subjects

RADAR in aeronautics, CLUTTER (Radar), ENCYCLOPEDIAS & dictionaries, POWER spectra, MACHINE learning, NONLINEAR regression

Abstract

Sparse recovery space–time adaptive processing (SR-STAP) technology improves the moving target detection performance of airborne radar. However, the sparse recovery method with a fixed dictionary usually leads to an off-grid effect. This paper proposes a STAP algorithm for airborne radar based on dictionary and clutter power spectrum joint correction (DCPSJC-STAP). The algorithm first performs nonlinear regression in a non-stationary clutter environment with unknown yaw angles, and it corrects the corresponding dictionary for each snapshot by updating the clutter ridge parameters. Then, the corrected dictionary is combined with the sparse Bayesian learning algorithm to iteratively update the required hyperparameters, which are used to correct the clutter power spectrum and estimate the clutter covariance matrix. The proposed algorithm can effectively overcome the off-grid effect and improve the moving target detection performance of airborne radar in actual complex clutter environments. Simulation experiments verified the effectiveness of this algorithm in improving clutter estimation accuracy and moving target detection performance. [ABSTRACT FROM AUTHOR]

Published

2024

9. Frequency Diversity Arc Array with Angle-Distance Two-Dimensional Broadening Null Steering for Sidelobe Suppression.

Author

Xu, Wei, Tian, Ying, Huang, Pingping, Tan, Weixian, and Qi, Yaolong

Subjects

ANGLES, STRUCTURAL models, PROBLEM solving

Abstract

The frequency diversity arc array (FDAA) improves the structure of the traditional frequency diversity array (FDA) from a linear array structure to an arc array structure, so that the FDAA not only has the advantages of the FDA but also has a large angle and omnidirectional scanning capability. However, when it is equivalent to a linear array, this arc-shaped structure will lead to the phenomenon of inverse density weighting, which leads to a higher sidelobe level of the FDAA beam pattern. In order to solve the problem of a high sidelobe level at a certain position of the FDAA, a frequency diversity arc array with angle-distance two-dimensional broadening null steering is proposed for sidelobe suppression. Using a structural model of the FDAA, the problem of the high sidelobe was analyzed. The linear constrained minimum variance (LCMV) method was used to generate a null with a certain width at the position of the fixed strong sidelobe level in the angle domain and the distance domain of the FDAA beam pattern, to reduce the FDAA sidelobe level. Then, the angle domain and distance domain fixed positions of the FDAA were simulated to generate the null beam pattern. The simulation results verified the effectiveness of this method for reducing the sidelobe level. [ABSTRACT FROM AUTHOR]

Published

2024

10. Beampattern Synthesis and Optimization Method Based on Circular Frequency Diverse Array Engineering Model.

Author

Xu, Wei, Pei, Changyu, Huang, Pingping, Tan, Weixian, and Gao, Zhiqi

Subjects

ENGINEERING models, ANTENNAS (Electronics)

Abstract

The frequency diverse array (FDA) is capable of generating range-angle-dependent beampatterns by introducing a tiny frequency offset to the transmit carrier frequency of each array element. However, the beam-scanning potential of conventional linear FDA applications is limited, notably in their incapacity for 360° omnidirectional scanning. This paper introduces a method that leverages the geometric configuration of circular frequency diverse arrays (CFDAs) for synthesizing and optimizing beampatterns through a practical engineering approach. Initially, we compute the structural parameters and configurations of CFDA. Subsequently, the isophase plane is utilized to adjust the phase of each array element. Ultimately, the CFDA structure is used to optimize the non-uniform frequency offset, and the beampattern, which is capable of 360° omnidirectional scanning, is realized by low sidelobe optimization. Simulation results affirm that the CFDA antenna, as per the actual engineering model, possesses precise dot-shaped beampattern scanning abilities across both range and angle dimensions. [ABSTRACT FROM AUTHOR]

Published

2024

11. Unsupervised Change Detection Using Ground-based Radar Image

Author

HUANG Pingping, REN Huifang, TAN Weixian, DUAN Yinghong, XU Wei, and LIU Fang

Subjects

ground-based radar image, change detection, unsupervised, coherence coefficient, improved fuzzy c-means (fcm), Electricity and magnetism, QC501-766

Abstract

Ground-based radar is a microwave remote sensing imaging technology that has been gradually developed throughout the past 20 years so that it has become mature. At present, it has been widely used in monitoring geological disasters such as landslides and collapses. Ground-based radars can detect microvariations in target areas through the principle of interferometry. However, due to human factors, geological factors, and meteorological factors, the radar image of the monitored area is incoherent, which makes long-term quantitative monitoring difficult. Therefore, further developing the application of change detection while considering quantitative monitoring is urgent, to provide effective information on long-term changes and comprehensively understand the dynamic changes in the monitored area. To solve the above problems, an unsupervised change detection method using ground-based radar images and based on an improved Fuzzy C-Means clustering (FCM) algorithm is proposed in this paper. In this method, for the first time, the Nonsubsampled Contourlet Transform (NSCT) is performed on the coherence coefficient map and the mean log ratio map to obtain the fusion difference map. Then, principal component analysis is used to extract the feature vectors of each pixel in the fusion difference image. The FCM is improved according to the characteristics of the ground-based radar images. The improved FCM is used to cluster the feature vectors of each pixel to obtain the change detection result. A ground-based radar LSA was used to monitor the treatment process of a dam in southwest China. During the monitoring process, landslides occurred in the monitored area affected by precipitation and other factors. This method is used to detect the change of the radar image before and after the landslide. The results show that the proposed method allows for easier clustering and segmenting, and the change detection results can significantly reduce the noise points while retaining the change area.

Published

2020

12. An Adaptive Polarimetric Target Decomposition Algorithm Based on the Anisotropic Degree.

Author

Huang, Pingping, Li, Baoyu, Li, Xiujuan, Tan, Weixian, Xu, Wei, and Chen, Yuejuan

Subjects

ALGORITHMS, GRASSLANDS, SCATTERING (Mathematics)

Abstract

Polarimetric target decomposition algorithms have played an important role in extracting the scattering characteristics of buildings, crops, and other fields. However, there is limited research on the scattering characteristics of grasslands and a lack of volume scattering models established for grasslands. To improve the accuracy of the polarimetric target decomposition algorithm applicable to grassland environments, this paper proposes an adaptive polarimetric target decomposition algorithm (APD) based on the anisotropy degree (A). The adaptive volume scattering model is used in APD to model volume scattering in forest and grassland regions separately by adjusting the value of A. When A > 1, the particle shape becomes a disk, and the grassland canopy is approximated as a cloud layer composed of randomly oriented disk particles; when A < 1, the particle shape is a needle, simulating the scattering mechanism of forests. APD is applied to an L-band AirSAR dataset from San Francisco, a C-band AirSAR dataset from Hunshandak grassland in Inner Mongolia Autonomous Region, and an X-band COSMO-SkyMed dataset from Xiwuqi grassland in Inner Mongolia Autonomous Region to verify the effectiveness of this method. Comparison studies are carried out to test the performance of APD over several target decomposition algorithms. The experimental results show that APD outperforms the algorithms tested in terms of this study in decomposition accuracy for grasslands and forests on different bands of data. [ABSTRACT FROM AUTHOR]

Published

2024

13. A Space-Borne SAR Azimuth Multi-Channel Quantization Method.

Author

Xu, Wei, Bai, Lu, Huang, Pingping, Tan, Weixian, and Dong, Yifan

Subjects

SYNTHETIC aperture radar, AZIMUTH, THERMAL noise, RANDOM noise theory, UNITS of time

Abstract

The space-borne synthetic aperture radar (SAR) azimuth multi-channel system has extensive applications because it can achieve high-resolution and wide-swath radar imaging. The thermal noise generated by the radar receiver of each channel during operation will cause an imbalance between channels. If the echoes of each channel are quantized with the same number of bits without considering the influence of thermal noise, false targets will appear in the imaging consequences. Considering that the thermal noise generated in the receiver will affect the quantization process of the space-borne SAR azimuth multi-channel system, a new space-borne SAR azimuth multi-channel quantization method is proposed to improve this problem. Firstly, the pure noise power of the receiver is calculated without transmitting the radar signal. The signal power is estimated by subtracting the pure noise power from the total power. Then, the average value of the radar echo signal minus k times the standard deviation is used as the left endpoint of the original data amplitude range, and the average value of the radar echo signal plus k times the standard deviation is used as the right endpoint of the original data amplitude range. The original echo data after adjusting the amplitude range is quantified. This method can effectively reduce the influence of thermal noise and random outliers in the receiver on quantization and suppress the appearance of false targets. Finally, simulation is used to confirm the viability of the suggested quantization approach. [ABSTRACT FROM AUTHOR]

Published

2024

14. A Reduced Sparse Dictionary Reconstruction Algorithm Based on Grid Selection.

Author

Gao, Zhiqi, Zhao, Caimei, Huang, Pingping, Xu, Wei, and Tan, Weixian

Subjects

ENCYCLOPEDIAS & dictionaries, ALGORITHMS, SPACETIME, BOOSTING algorithms, ATOMS, IMAGE reconstruction algorithms, CLUTTER (Radar), SPARSE approximations

Abstract

A sparse dictionary reconstruction algorithm based on grid selection is introduced to solve the grid mismatch when using the sparse recovery space time adaptive processing (SR-STAP) algorithm. First, the atom most closely related to clutter is selected from the traditional dictionary through the spectral value dimensionality reduction method. The local mesh is divided around the selected atoms to create mesh cells, and the mesh cells that are most likely to appear in the real clutter points are judged according to the local selection iteration criteria. In this way, the mesh spacing is refined, the local mesh selection is carried out step by step, and the optimal atoms in the local region are constantly adjusted and selected to narrow the search region until the iteration termination condition is met. Finally, the space-time plane is divided using a novel meshing technique that centers around the optimal atom. By removing atoms beyond the maximum range of spatial and Doppler frequencies, the simplified sparse dictionary can overcome the mesh mismatch problem. The simulation results demonstrate that the algorithm enhances the sparse recovery accuracy of clutter space-time spectrum, mitigates the mesh mismatch effect, and boosts STAP performance. [ABSTRACT FROM AUTHOR]

Published

2024

15. Research on Time Series Monitoring of Surface Deformation in Tongliao Urban Area Based on SBAS-PS-DS-InSAR.

Author

Chen, Yuejuan, Ding, Cong, Huang, Pingping, Yin, Bo, Tan, Weixian, Qi, Yaolong, Xu, Wei, and Du, Siai

Subjects

CITIES & towns, DEFORMATION of surfaces, SYNTHETIC aperture radar, TIME series analysis, STANDARD deviations, URBAN planning

Abstract

As urban economies flourish and populations become increasingly concentrated, urban surface deformation has emerged as a critical factor in city planning that cannot be overlooked. Surface deformation in urban areas can lead to deformations in structural supports of infrastructure such as road bases and bridges, thereby posing a serious threat to public safety and creating significant safety hazards. Consequently, research focusing on the monitoring of urban surface deformation holds paramount importance. Interferometric synthetic aperture radar (InSAR), as an important means of earth observation, has all-day, wide-range, high-precision, etc., characteristics and is widely used in the field of surface deformation monitoring. However, traditional solitary InSAR techniques are limited in their application scenarios and computational characteristics. Additionally, the manual selection of ground control points (GCPs) is fraught with errors and uncertainties. Permanent scatterers (PS) can maintain high interferometric coherence in man-made building areas, and distributed scatterers (DS) usually show moderate coherence in areas with short vegetation; the combination of DS and PS solves the problem of manually selecting GCPs during track re-flattening and regrading, which affects the monitoring results. In this paper, 45 Sentinel-1B data from 16 February 2019 to 14 December 2021 are used as the data source in the urban area of Horqin District, Tongliao City, Inner Mongolia Autonomous Region, for example. A four-threshold (coherence coefficient threshold, FaSHPS adaptive threshold, amplitude divergence index threshold, and deformation velocity interval) GCPs point screening method for PS-DS, as well as a Small Baseline Subset-Permanent Scatterers-Distributed Scatterers-Interferometric Synthetic Aperture Radar (SBAS-PS-DS-InSAR) method for selecting PS and DS points as ground control points for orbit refinement and re-flattening, are proposed. The surface deformation results obtained using the Small Baseline Subset Interferometric Synthetic Aperture Radar (SBAS-InSAR) and the SBAS-PS-DS-InSAR proposed in this paper were comparatively analysed and verified. The maximum cumulative line-of-sight settlements were −90.78 mm and −83.68 mm, and the maximum cumulative uplifts are 74.94 mm and 97.56 mm, respectively; the maximum annual average line-of-sight settlements are −35.38 mm/y and −30.38 mm/y, and the maximum annual average uplifts are 25.27 mm/y and 27.92 mm/y. The results were evaluated and analysed in terms of correlation, mean absolute error (MAE), and root mean square error (RMSE). The deformation results of the two InSAR methods were evaluated and analysed in terms of correlation, MAE, and RMSE. The errors show that the Pearson correlation coefficients between the vertical settlement results obtained using the SBAS-PS-DS-InSAR method and the GPS monitoring results were closer to 1. The maximum MAE and RMSE were 13.7625 mm and 14.8004 mm, respectively, which are within the acceptable range; this confirms that the monitoring results of the SBAS-PS-DS-InSAR method were better than those of the original SBAS-InSAR method. SBAS-InSAR method, which is valid and reliable. The results show that the surface deformation results obtained using the SBAS-InSAR, SBAS-PS-DS-InSAR, and GPS methods have basically the same settlement locations, extents, distributions, and temporal and spatial settlement patterns. The deformation results obtained using these two InSAR methods correlate well with the GPS monitoring results, and the MAE and RMSE are within acceptable limits. By comparing the deformation information obtained using multiple methods, the surface deformation in urban areas can be better monitored and analysed, and it can also provide scientific references for urban municipal planning and disaster warning. [ABSTRACT FROM AUTHOR]

Published

2024

16. An Airborne Arc Array Synthetic Aperture Radar Vibration Error Compensation Method.

Author

Xiao, Mengxue, Huang, Pingping, Xu, Wei, Tan, Weixian, Gao, Zhiqi, and Qi, Yaolong

Subjects

SYNTHETIC apertures, SYNTHETIC aperture radar, MULTIPLICATION

Abstract

Compared to conventional radars, arc array synthetic aperture radar (SAR) enables wide-area observation under ideal conditions. However, helicopters carrying arc array SAR platforms are generally smaller in size and more sensitive to vibration, which has a greater impact on the imaging quality. In this paper, the vibration error of the arc array SAR platform is investigated, and a vibration error model of the arc array SAR platform is established. Based on the study of the vibration error model, a vibration phase estimation and compensation algorithm based on the delayed conjugate multiplication method is proposed. In the first step, distance pulse pressure processing is performed on the echo signal. In the second step, the pulse pressure signals and their delays in the same distance unit are subjected to conjugate multiplication, and the phase of the signal after conjugate multiplication is extracted. The extracted phase is then amplitude- and phase-compensated to estimate the vibration phase. In the third step, the vibration phase is compensated in the azimuthal direction of the distance pulse pressure signal, and the pairwise echo is eliminated, which completes the compensation of the airborne arc array SAR vibration platform. [ABSTRACT FROM AUTHOR]

Published

2024

17. A Parameter-Free Pixel Correlation-Based Attention Module for Remote Sensing Object Detection.

Author

Guan, Xin, Dong, Yifan, Tan, Weixian, Su, Yun, and Huang, Pingping

Subjects

OBJECT recognition (Computer vision), COMPUTER vision, FEATURE extraction, PEARSON correlation (Statistics), DETECTION alarms, EYE tracking, MARKOV random fields

Abstract

Remote sensing image object detection is a challenging task in the field of computer vision due to the complex backgrounds and diverse arrangements of targets in remote sensing images, forming intricate scenes. To overcome this challenge, existing object detection models adopt rotated target detection methods. However, these methods often lead to a loss of semantic information during feature extraction, specifically regarding the insufficient consideration of element correlations. To solve this problem, this research introduces a novel attention module (EuPea) designed to effectively capture inter-elemental information in feature maps and generate more powerful feature maps for use in neural networks. In the EuPea attention mechanism, we integrate distance information and Pearson correlation coefficient information between elements in the feature map. Experimental results show that using either type of information individually can improve network performance, but their combination has a stronger effect, producing an attention-weighted feature map. This improvement effectively enhances the object detection performance of the model, enabling it to better comprehend information in remote sensing images. Concurrently, this also improves missed detections and false alarms in object detection. Experimental results obtained on the DOTA, NWPU VHR-10, and DIOR datasets indicate that, compared with baseline RCNN models, our approach achieves respective improvements of 1.0%, 2.4%, and 1.8% in mean average precision (mAP). [ABSTRACT FROM AUTHOR]

Published

2024

18. Research Progress on Three-dimensional SAR Imaging Techniques

Author

Hong Wen, Wang Yanping, Lin Yun, Tan Weixian, and Wu Yirong

Subjects

3-D SAR imaging, Multi-baseline SAR, Array 3-D SAR, Curvilinear SAR, Circular SAR, Multibaseline Circular SAR, Electricity and magnetism, QC501-766

Abstract

Conventional Synthetic Aperture Radar (SAR) moves along a straight line and forms a linear synthetic apertures. It can only obtain the two-dimensional (2-D) image of illuminated scene that is the projection of the three-dimensional (3-D) real scene onto a slant plane. The slant plane 2-D SAR image, however, suffers from layover and foreshortening effects. 3-D SAR imaging enables 3-D resolving capability by extending the acquisition of frequency information from 2-D to 3-D. It can obtain the 3-D distribution of scattering centers; therefore, it solves the geometric deformation problems of layover and foreshortening. 3-D SAR imaging has become a trending topic in research on SAR techniques worldwide. In this paper, we first introduced the concept of 3-D SAR imaging and several typical 3-D SAR imaging modes. Furthermore, it provides a discussion on research progress at home and abroad, particularly focusing on the progress of our research team. Finally, future research prospects are presented.

Published

2018

19. Using the Displaced Phase Center Azimuth Multiple Beams Technique with Spaceborne Synthetic Aperture Radar Systems for Multichannel Reconstruction of Accelerated Moving Targets.

Author

Xu, Wei, Chen, Yu, Huang, Pingping, Tan, Weixian, and Qi, Yaolong

Subjects

SYNTHETIC aperture radar, AZIMUTH, DOPPLER effect, IMAGE reconstruction, PARAMETER estimation

Abstract

The displaced phase center multiple azimuth beams (DPCMAB) technique can help spaceborne synthetic aperture radar (SAR) systems obtain the high-resolution wide-swath (HRWS) imaging capacity, and azimuth multichannel reconstruction is usually required due to azimuth non-uniform sampling. Compared with stationary and moving targets, the range history and azimuth signal model of the moving target with an acceleration are obviously different. The azimuth multichannel signal model of an accelerated moving target is established, and the relationship between acceleration and Doppler parameters is analyzed. Furthermore, the impact of the acceleration on azimuth multichannel reconstruction and imaging results is simulated and analyzed. According to the azimuth multichannel signal model, an azimuth multichannel reconstruction approach for accelerated moving targets is proposed. The key point of the proposed reconstruction approach is the modified azimuth multichannel matrix, which is related not only to azimuth and slant velocities but also accelerations. The target's velocities and accelerations are obtained using multiple Doppler parameter estimations. Compared with the conventional method of processing the raw data of accelerated moving targets, this proposed method could distinctly suppress image defocusing and pairs of false targets. Simulation results on point targets validate the proposed azimuth multichannel reconstruction approach. [ABSTRACT FROM AUTHOR]

Published

2023

20. Sparse Microwave Imaging Algorithm Based on L 1/2 Threshold Iteration and an Approximate Observation Operator.

Author

Gao, Zhiqi, Li, Xin, Huang, Pingping, Xu, Wei, and Tan, Weixian

Subjects

MICROWAVE imaging, THRESHOLDING algorithms, SIGNAL reconstruction, MATCHED filters, ALGORITHMS, COMPUTATIONAL complexity

Abstract

Aiming at the problems of synthetic-aperture radar (SAR), such as high sampling rate and vulnerability to noise interference in imaging, a sparse reconstruction algorithm based on approximate observation and L1/2 threshold iteration is proposed in this paper. To solve the problem of the large dimension and high computational complexity of the measurement matrix, a sparse reconstruction model based on approximate observation is constructed, and a threshold iterative algorithm to rapidly solve the L1/2 regularization problem is introduced, which can realize sparse signal reconstruction with fewer sampling data and quickly solve the problem. The simulation results of point targets and the measured data of spaceborne SAR show that compared with the traditional matched filtering algorithm and L1 threshold algorithm based on a two-step iteration, the proposed sparse reconstruction algorithm has a faster iteration speed and improves the image quality. [ABSTRACT FROM AUTHOR]

Published

2023

21. System Design and Echo Preprocessing of Spaceborne Squinted Two-Dimensional Beam Scanning Synthetic Aperture Radar.

Author

Xu, Wei, Lu, Xuhang, Huang, Pingping, Tan, Weixian, Gao, Zhiqi, and Qi, Yaolong

Subjects

SYNTHETIC aperture radar, SPACE-based radar, SYNTHETIC apertures, SYSTEMS design, AZIMUTH, CELL migration, IMAGING systems

Abstract

Conventional squinted sliding spotlight synthetic aperture radar (SAR) imaging suffers from substantial swath width reduction and complex processing requirements due to the continuous variation in the squint angle and the large range cell migration (RCM) throughout the data acquisition interval. A novel two-dimensional (2D) beam scanning mode for high-resolution wide swath (HRWS) imaging is proposed. The key to the novel imaging mode lies in the synchronous scanning of azimuth and range beams, allowing for a broader and more flexible imaging swath with a high geometric resolution. Azimuth beam scanning from fore to aft was used to improve the azimuth resolution, while range beam scanning was adopted to illuminate the oblique wide swath to avoid the large RCM and the serious swath width reduction. Compared with the conventional sliding spotlight mode, both the swath width and swath length could be extended. According to the echo model of this imaging mode, an echo signal preprocessing approach is proposed. The key points of this approach are range data extension and azimuth data upsampling. A designed system example with a resolution of 0.5 m, swath width of 60 km, and azimuth coverage length of 134 km is presented. Furthermore, a simulation experiment on point targets was carried out. Both the presented system example and imaging results of point targets validated the proposed imaging mode. [ABSTRACT FROM AUTHOR]

Published

2023

22. Swin-YOLO for Concealed Object Detection in Millimeter Wave Images.

Author

Huang, Pingping, Wei, Ran, Su, Yun, and Tan, Weixian

Subjects

MILLIMETER waves, PUBLIC safety

Abstract

Concealed object detection in millimeter wave (MMW) images has gained significant attention in the realm of public safety, primarily due to its distinctive advantages of non-hazardous and non-contact operation. However, this undertaking confronts substantial challenges in practical applications, owing to the inherent limitations of low imaging resolution, small concealed object size, intricate environmental noise, and the need for real-time performance. In this study, we propose Swin-YOLO, an innovative single-stage detection model built upon transformer layers. Our approach encompasses several key contributions. Firstly, the integration of Local Perception Swin Transform Layers (LPST Layers) enhanced the network's capability to acquire contextual information and local awareness. Secondly, we introduced a novel feature fusion layer and a specialized prediction head for detecting small targets, effectively leveraging the network's shallow feature information. Lastly, a coordinate attention (CA) module was seamlessly incorporated between the neck network and the detection head, augmenting the network's sensitivity towards critical regions of small objects. To validate the efficacy and feasibility of our proposed method, we created a new MMW dataset containing a large number of small concealed objects and conducted comprehensive experiments to evaluate the effectiveness of overall and partial improvements, as well as computational efficiency. The results demonstrated a remarkable 4.7% improvement in the mean Average Precision (mAP) for Swin-YOLO compared with the YOLOv5 baseline. Moreover, when compared with other enhanced transformer-based models, Swin-YOLO exhibited a superior accuracy and the fastest inference speed. The proposed model showcases enhanced performance and holds promise for advancing the capabilities of real-world applications in public safety domains. [ABSTRACT FROM AUTHOR]

Published

2023

23. Auto Learner of Objects Co-Occurrence Knowledge for Object Detection in Remote Sensing Images.

Author

Zheng, Kunlong, Dong, Yifan, Xu, Wei, Tan, Weixian, and Huang, Pingping

Abstract

Object detection in remote sensing images (RSIs) is crucial for ground observation applications such as land surveying, urban planning, and precision agriculture. With the advent of convolutional neural networks, the performance of object detection in RSIs has been significantly improved. However, most studies have focused exclusively on the feature extraction, processing, and representation of geographical objects. The lack of integration of relevant common-sense knowledge has led to some obviously missed detections and illogical false alarms in the detection results. This letter proposes a novel and widely applicable approach for updating and fusing object co-occurrence knowledge into a two-stage multiclass object detection framework, called Auto Learner of Co-occurrence. The method captures the correlation between different object categories during the training process with the Co-occurrence Knowledge Updating module and utilizes the established co-occurrence weight matrix to enhance classification with the Knowledge Fusing module. The effectiveness and adaptability of the proposed method were validated through experiments on two multiclass object detection datasets using four popular two-stage detectors. The experiments also indicate that the speed penalty and the parameter increase resulting from the method are negligible. [ABSTRACT FROM AUTHOR]

Published

2023

24. System Design and Signal Processing in Spaceborne Squint Sliding Spotlight SAR with Sub-Aperture Block-Varying PRF.

Author

Xu, Wei, Zhang, Zhuo, Huang, Pingping, Tan, Weixian, and Qi, Yaolong

Subjects

SPACE-based radar, SIGNAL processing, SYSTEMS design, STRABISMUS, SYNTHETIC aperture radar, MERGERS & acquisitions

Abstract

To tackle the problems of Doppler spectrum, aliasing caused by azimuth beam scanning and azimuthal serious non-uniform sampling in squint sliding spotlight synthetic aperture radar (SAR) with varying repetition frequency technology, the azimuth sampling method of sub-aperture block-varying pulse repetition frequency (SBV-PRF) is proposed, where the sub-aperture division judgement makes the azimuth acquisition time of each sub-block small enough so that the Doppler bandwidth caused by the Doppler center change can be ignored. Based on the echo signal characteristics of a SBV-PRF transmission scheme, an azimuth pre-processing method combining SBV-PRF transmission scheme with sub-aperture division is proposed. Using this method, de-skewing is first performed on each set of sub-aperture data to eliminate the additional Doppler bandwidth introduced by the squint angle, and then the azimuth signal resampling is performed to ensure different sub-aperture data have the same sampling rate. The SBV-PRF technology reduces the difficulty of azimuth signal pre-processing while ensuring the complete acquisition of the complete echo data of the squint sliding spotlight mode. The effectiveness of the SBV-PRF system design and the signal processing method is verified by the point target echo simulation and imaging simulation results. [ABSTRACT FROM AUTHOR]

Published

2023

25. An improved null steering digital beamformer based on multi-group time delays for echo separation in HRWS SAR.

Author

Yu, Qi, Xu, Wei, Huang, Pingping, Tan, Weixian, and Qi, Yaolong

Subjects

BEAM steering, SPACE-based radar, SYNTHETIC aperture radar

Abstract

Digital beamforming with null steering in elevation can be used to separate echoes corresponding to different sub-pulses, but the pulse extension loss will decrease performance on echo separation. To resolve this problem, an improved null steering beamformer based on multi-group time delays is proposed. In the proposed beamformer, the phase weighting matrix is multiplied and the multi-group time delays are used to improve the coherence between echoes from different channels. Then, the modified phase weighing matrix for null steering is introduced to further improve the capacity of echo separation. Compared with the conventional null steering beamformer, the multi-group time delays can provide the more accurate time delay compensation for better echo separation. Simulation results on both point and distributed targets validate the proposed beamformer. [ABSTRACT FROM AUTHOR]

Published

2023

26. Integration of DInSAR-PS-Stacking and SBAS-PS-InSAR Methods to Monitor Mining-Related Surface Subsidence.

Author

Chen, Yuejuan, Dong, Xu, Qi, Yaolong, Huang, Pingping, Sun, Wenqing, Xu, Wei, Tan, Weixian, Li, Xiujuan, and Liu, Xiaolong

Subjects

MINE subsidences, COAL mining, LAND subsidence, SURFACE area, SURFACE cracks

Abstract

Over-exploitation of coal mines leads to surface subsidence, surface cracks, collapses, landslides, and other geological disasters. Taking a mining area in Nalintaohai Town, Ejin Horo Banner, Ordos City, Inner Mongolia Autonomous Region, as an example, Sentinel-1A data from January 2018 to October 2019 were used as the data source in this study. Based on the high interference coherence of the permanent scatterer (PS) over a long period of time, the problem of the manual selection of ground control points (GCPs) affecting the monitoring results during refinement and re-flattening is solved. A DInSAR-PS-Stacking method combining the PS three-threshold method (the coherence coefficient threshold, amplitude dispersion index threshold, and deformation velocity interval) is proposed as a means to select ground control points for refinement and re-flattening, as well as a means to obtain time-series deformation by weighted stacking processing. A SBAS-PS-InSAR method combining the PS three-threshold method to select PS points as GCPs for refinement and re-flattening is also proposed. The surface deformation results monitored by the DInSAR-PS-Stacking and SBAS-PS-InSAR methods are analyzed and verified. The results show that the subsidence location, range, distribution, and space–time subsidence law of surface deformation results obtained by DInSAR-PS-Stacking, SBAS-PS-InSAR, and GPS methods are basically the same. The deformation results obtained by these two InSAR methods have a good correlation with the GPS monitoring results, and the MAE and RMSE are within the acceptable range. The error showed that the edge of the subsidence basin was small and that the center was large. Both methods were found to be able to effectively monitor the coal mine, but there were also shortcomings. DInSAR-PS-Stacking has a strong ability to monitor the settlement center. SBAS-PS-InSAR performed well in monitoring slow and small deformations, but its monitoring of the settlement center was insufficient. Considering the advantages of these two InSAR methods, we proposed fusing the time-series deformation results obtained using these two InSAR methods to allow for more reliable deformation results and to carry out settlement analysis. The results showed that the automatic two-threshold (deformation threshold and average coherence threshold) fusion was effective for monitoring and analysis, and the deformation monitoring results are in good agreement with the actual situation. The deformation information obtained by the comparison, and fusion of multiple methods can allow for better monitoring and analysis of the mining area surface deformation, and can also provide a scientific reference for mining subsidence control and early disaster warning. [ABSTRACT FROM AUTHOR]

Published

2023

27. Beampattern Synthesis and Optimization for Frequency Diverse Arc Array Based on the Virtual Element.

Author

Xu, Wei, Deng, Zhuo, Huang, Pingping, Tan, Weixian, and Gao, Zhiqi

Subjects

ARCHES, AZIMUTH, VOLTAGE-controlled oscillators, DENSITY

Abstract

With its special, arch-shaped array structure, a frequency diverse arc array (FDAA) can perform beam scanning in 360 degrees in azimuth and in arbitrary ranges by selectively activating array elements in different positions, utilizing array element phase compensation, and adopting a frequency offset design. In this paper, a beampattern synthesis and optimization method for FDDA using the virtual array element based on the geometric configuration of FDDA is proposed. First, the position of the virtual array element is determined by the direction of the target, and then activated array elements are selected. Afterwards, the frequency offset of each array element is set up on the equiphase surface to obtain the dot-shaped beampattern. Finally, amplitude weighting is introduced to suppress the increased sidelobe level of the dot-shaped beampattern, which is caused by inverse density weighting of the arch-shaped array structure. Simulation results validate the proposed method for beampattern synthesis and optimization in FDAA. [ABSTRACT FROM AUTHOR]

Published

2023

28. DLSLA 3-D SAR imaging algorithm for off-grid targets based on pseudo-polar formatting and atomic norm minimization

Author

Bao, Qian, Han, Kuoye, Peng, Xueming, Hong, Wen, Zhang, Bingchen, and Tan, Weixian

Published

2016

29. A Modified Keystone-Based Forward-Looking Arc Array Synthetic Aperture Radar 3D Imaging Method.

Author

Zhu, Xiaofan, Huang, Pingping, Xu, Wei, Tan, Weixian, and Qi, Yaolong

Subjects

SYNTHETIC aperture radar, SYNTHETIC apertures, THREE-dimensional imaging, IMAGING systems, SPATIAL resolution, SPATIAL systems, AZIMUTH

Abstract

An arc array synthetic aperture radar (AA-SAR) is a new type of omnidirectional observation and imaging system. Based on linear array 3D imaging, this paper introduces a keystone algorithm combined with the arc array SAR 2D imaging method and proposes a modified 3D imaging algorithm based on keystone transformation. The first step is to discuss the target azimuth angle, retain the far-field approximation method of the first-order term, analyze the influence of the forward motion of the platform on the along-track position, and realize the two-dimensional focusing of the target slant range–azimuth direction. The second step is to redefine a new azimuth angle variable in the slant-range along-track imaging and use the keystone-based processing algorithm in the range frequency domain to eliminate the coupling term generated by the array angle and the slant-range time. The corrected data are used to perform along-track pulse compression to obtain the focused image of the target and realize the three-dimensional imaging of the target. Finally, in this article, the spatial resolution of the AA-SAR system in the forward-looking state is analyzed in detail, and the change in the spatial resolution of the system and the effectiveness of the algorithm are verified through simulation. [ABSTRACT FROM AUTHOR]

Published

2023

30. A Method for Predicting Landslides Based on Micro-Deformation Monitoring Radar Data.

Author

Tan, Weixian, Wang, Yadong, Huang, Pingping, Qi, Yaolong, Xu, Wei, Li, Chunming, and Chen, Yuejuan

Subjects

*LANDSLIDES, *LANDSLIDE prediction, *RADAR, *NEWTON-Raphson method, *DATA mining, *TIME series analysis

Abstract

Mine slope landslides seriously threaten the safety of people's lives and property in mining areas. Landslide prediction is an effective way to reduce losses due to such disasters. In recent years, micro-deformation monitoring radar has been widely used in mine slope landslide monitoring. However, traditional landslide prediction methods are not able to make full use of the diversified monitoring data from these radars. This paper proposes a landslide time prediction method based on the time series monitoring data of micro-deformation monitoring radar. Specifically, deformation displacement, coherence and deformation volume, and the parametric degree of deformation (DOD) are calculated and combined with the use of the tangent angle method. Finally, the effectiveness of the method is verified by using measured data of a landslide in a mining area. The experimental results show that our proposed method can be used to identify the characteristics of an imminent sliding slope and landslide in advance, providing monitoring personnel with more reliable landslide prediction results. [ABSTRACT FROM AUTHOR]

Published

2023

31. Generalized pseudopolar format algorithm for radar imaging with highly suboptimal aperture length

Author

Han, KuoYe, Wang, YanPing, Chang, XiangKe, Tan, WeiXian, and Hong, Wen

Published

2015

32. Downward looking sparse linear array 3D SAR imaging algorithm based on back-projection and convex optimization

Author

Bao, Qian, Peng, Xueming, Wang, Yanping, Tan, Weixian, and Hong, Wen

Published

2014

33. Cascaded U-Net with Training Wheel Attention Module for Change Detection in Satellite Images.

Author

Adil, Elyar, Yang, Xiangli, Huang, Pingping, Liu, Xiaolong, Tan, Weixian, and Yang, Jianxi

Subjects

DEEP learning, IMAGE analysis, REMOTE sensing, REMOTE-sensing images, OPTICAL remote sensing

Abstract

Change detection is an important application of remote sensing image interpretation, which identifies changed areas of interest from a pair of bi-temporal remote sensing images. Various deep-learning-based approaches have demonstrated promising results and most of these models used an encoder–decoder shape such as U-Net for segmentation of changed areas. In order to obtain more refined features, this paper introduces a change detection model with cascaded U-Net. The proposed network architecture contains four cascaded U-Nets with ConvNeXT blocks. With a patch embedding layer, the cascaded structure can improve detection results with acceptable computational overhead. To facilitate the training of the cascaded N-Nets, we proposed a novel attention mechanism called the Training whEel Attention Module (TEAM). During the training phase, TEAM aggregates outputs from different stages of cascaded structures and shifts attention from outputs from shallow stages to outputs from deeper stages. The experimental results show that our cascaded U-Net architecture with TEAM achieves state-of-the-art performance in two change detection datasets without extra training data. [ABSTRACT FROM AUTHOR]

Published

2022

34. Azimuth Full-Aperture Processing of Spaceborne Squint SAR Data with Block Varying PRF.

Author

Zhang, Zhuo, Xu, Wei, Huang, Pingping, Tan, Weixian, Gao, Zhiqi, and Qi, Yaolong

Subjects

AZIMUTH, SYNTHETIC aperture radar, RESAMPLING (Statistics), STRABISMUS, BLOCK codes

Abstract

The block varying pulse repetition frequency (BV-PRF) scheme applied to spaceborne squint sliding-spotlight synthetic aperture radar (SAR) can resolve large-range cell migration (RCM) and reduce azimuth signal non-uniformity. However, in the BV-PRF scheme, different raw data blocks have different PRFs, and the raw data in each block are insufficiently sampled. To resolve the two problems, a novel azimuth full-aperture pre-processing method is proposed to handle the SAR raw data formed by the BV-PRF scheme. The key point of the approach is the resampling of block data with different PRFs and the continuous splicing of azimuth data. The method mainly consists of four parts: de-skewing, resampling, azimuth continuous combination, and Doppler history recovery. After de-skewing, the raw data with different PRFs can be resampled individually to obtain a uniform azimuth sampling interval, and an appropriate azimuth time shift is introduced to ensure the continuous combination of the azimuth signal. Consequently, the resulting raw data are sufficiently and uniformly sampled in azimuth, which could be well handled by classical SAR-focusing algorithms. Simulation results on point targets validate the proposed azimuth pre-processing approach. Furthermore, compared with methods to process SAR data with continuous PRF, the proposed method is more effective. [ABSTRACT FROM AUTHOR]

Published

2022

35. An Adjusted Frequency-Domain Algorithm for Arc Array Bistatic SAR Data with One-Moving Transmitter.

Author

Huang, Pingping, Hao, Lingxia, Tan, Weixian, Xu, Wei, and Qi, Yaolong

Subjects

SYNTHETIC aperture radar, TRANSMITTERS (Communication), AZIMUTH, SPATIAL resolution, TAYLOR'S series, CELL migration, ELECTRIC arc

Abstract

Arc array synthetic aperture radar (AA-SAR), which can observe the scene in all directions, breaks through the single view of traditional SAR. However, the concealment of AA-SAR is poor. To mitigate this, arc array bistatic SAR (AA-BiSAR) with the moving transmitter is proposed, it has the advantages of good concealment and can expand the imaging scene, and improve the flexibility of the system. The imaging geometry including the signal model is established, and a range frequency-domain algorithm based on keystone transform (KT) is proposed in this paper. In the first step, the slant range equation is approximated by Taylor series expansion to compensate for the residual phase caused by the transmitter motion. In the second step, the range cell migration between the range and azimuth is eliminated through the KT method in the range frequency-domain. In the third step, using the data after range cell migration correction in step 2, an azimuth pulse compression is performed to obtain the focused image. In addition, the spatial resolution of the AA-BiSAR system is analyzed in detail. Finally, three simulation results verify the effectiveness of the proposed algorithm and the change in the spatial resolution. [ABSTRACT FROM AUTHOR]

Published

2022

36. A Three-Dimensional Range Migration Algorithm for Downward-Looking 3D-SAR with Single-Transmitting and Multiple-Receiving Linear Array Antennas

Author

Du, Lei, Wang, Yanping, Hong, Wen, Tan, Weixian, and Wu, Yirong

Published

2010

37. Studies on MB-SAR 3D imaging algorithm using Yule-Walker method

Author

Wang, Bin, Wang, YanPing, Hong, Wen, Tan, WeiXian, and Wu, YiRong

Published

2010

38. Synthetic aperture radar tomography sampling criteria and three-dimensional range migration algorithm with elevation digital spotlighting

Author

Tan, WeiXian, Hong, Wen, Wang, YanPing, Lin, Yun, and Wu, YiRong

Published

2009

39. A Hybrid Polarimetric Target Decomposition Algorithm with Adaptive Volume Scattering Model.

Author

Li, Xiujuan, Liu, Yongxin, Huang, Pingping, Liu, Xiaolong, Tan, Weixian, Fu, Wenxue, and Li, Chunming

Subjects

POLARIMETRY, SYNTHETIC aperture radar, PIXELS, SURFACE scattering, ALGORITHMS, DYNAMIC models

Abstract

Previous studies have shown that scattering mechanism ambiguity and negative power issues still exist in model-based polarization target decomposition algorithms, even though deorientation processing is implemented. One possible reason for this is that the dynamic range of the model itself is limited and cannot fully satisfy the mixed scenario. To address these problems, we propose a hybrid polarimetric target decomposition algorithm (GRH) with a generalized volume scattering model (GVSM) and a random particle cloud volume scattering model (RPCM). The adaptive volume scattering model used in GRH incorporates GVSM and RPCM to model the volume scattering model of the regions dominated by double-bounce scattering and the surface scattering, respectively, to expand the dynamic range of the model. In addition, GRH selects the volume scattering component between GVSM and RPCM adaptively according to the target dominant scattering mechanism of fully polarimetric synthetic aperture radar (PolSAR) data. The effectiveness of the proposed method was demonstrated using AirSAR dataset over San Francisco. Comparison studies were carried out to test the performance of GRH over several target decomposition algorithms. Experimental results show that the GRH outperforms the algorithms we tested in this study in decomposition accuracy and reduces the number of pixels with negative powers, demonstrating that the GRH can significantly avoid mechanism ambiguity and negative power issues. [ABSTRACT FROM AUTHOR]

Published

2022

40. Continuous PRI Variation and Phase Center Adjustment for Azimuth Uniform Sampling in Staggered SAR.

Author

Xu, Wei, Hu, Jialuo, Huang, Pingping, Tan, Weixian, Gao, Zhiqi, and Dong, Yifan

Subjects

AZIMUTH, SYNTHETIC aperture radar, IRREGULAR sampling (Signal processing), COMPUTATIONAL complexity

Abstract

Staggered synthetic aperture radar (SAR) can effectively stagger range blind areas by periodically changing the pulse repetition interval (PRI), to achieve continuous imaging with an ultrawide swath. In conventional staggered SAR, azimuth samples are nonuniformly distributed due to the variable PRI, and complex resampling processing, such as best linear unbiased (BLU) interpolation and multichannel reconstruction processing, is required. In this article, a strict rule of PRI variation and phase center adjustment (PCA) is proposed for staggered SAR, to solve the problem of nonuniform azimuth sampling. In the proposed joint strategy of PRI variation and PCA, the relevant parameters for PCA are first determined. Then, the PRI sequence is designed according to PCA parameters to stagger blind ranges. Finally, the PCA rule is designed according to the designed PRI sequence and PCA parameters. During the data acquisition interval, the effective phase center is periodically adjusted pulse by pulse according to this rule, making the azimuth samples totally uniformly distributed. In addition, the discontinuously distributed missing samples can be estimated by signal estimation approaches. With the proposed joint rule of PRI variation and PCA, the emergence of false targets in imaging results can be avoided, and the complex resampling processing can be relieved to reduce the computational complexity. Simulation experiments on imaging results verify the advantages of this strategy. [ABSTRACT FROM AUTHOR]

Published

2022

41. RFI Suppression Based on Linear Prediction in Synthetic Aperture Radar Data.

Author

Xu, Wei, Xing, Weida, Fang, Chonghua, Huang, Pingping, and Tan, Weixian

Abstract

Radio frequency interference (RFI) sources pose threats to wideband synthetic aperture radar (SAR) systems and accurate SAR image interpretation. Since most of RFI sources are narrowband, notch filtering is a simple but effective method for RFI suppression. In this letter, a modified two-step notch filtering approach combined with linear prediction is proposed to improve the SAR image quality. The notch filtering is used to mitigate narrowband RFI energy, while the linear prediction is introduced to recover the missing range spectral component of the SAR raw data from the desired scene, which is removed together with RFI sources by the notch filter. Because of the Gibbs phenomenon in Fourier series, the small residual RFI energy after notch filtering is enough to cause image visual disturbances and affect the accuracy of the following missing range spectrum extrapolation. The two-step notch filtering with a limited bandwidth is applied for better RFI sources mitigation. Simulation results on both simulated targets and real SAR raw data validate the proposed approach. [ABSTRACT FROM AUTHOR]

Published

2021

42. FDA Beampattern Synthesis With Both Nonuniform Frequency Offset and Array Spacing.

Author

Xu, Wei, Zhang, Lihua, Bi, Hui, Huang, Pingping, and Tan, Weixian

Abstract

The frequency diverse array (FDA) can generate a beampattern with dual dependence on angle and range by adding a smaller frequency component to the carrier frequency. To overcome the range-angle dependent in the classical FDA, several FDA frameworks with nonuniform frequency offset are proposed to obtain a dot-shaped beampattern. To obtain the dot-shaped beampattern with better performance, a symmetry FDA with both nonuniform frequency offset and array spacing is proposed. The symmetry nonuniform frequency offset is adopted to generate the dot-shaped beampattern, whereas the nonuniform array spacing is introduced to suppress sidelobes in the both range and angle directions. Numerical simulation results validate the improved performances of the proposed FDA in terms of the suppressed sidelobe level and the improved anti-interference ability, compared with the symmetric logarithmic frequency offset FDA. [ABSTRACT FROM AUTHOR]

Published

2021

43. A Fast Far-Field Pseudopolar Format Algorithm for Ground-Based Arc 3-D SAR Imaging.

Author

Huang, Zengshu, Sun, Jinping, Tan, Weixian, Huang, Pingping, and Qi, Yaolong

Abstract

Compared with the conventional 3-D synthetic aperture radar (SAR) system, the arc 3-D SAR can achieve a wide azimuth observation extent. In this letter, a far-field pseudopolar format imaging algorithm for the ground-based arc 3-D SAR is presented. Different from the existing algorithms, the proposed algorithm exploits keystone formatting and fast Fourier transforms (FFTs) to obtain a pseudopolar grid in the elevation direction, then complex multiplications and FFTs are performed in the range-azimuth wavenumber domain to complete 3-D focusing. The advantages of this method are its low computational complexity and high efficiency. The sampling criteria and computational complexity are also discussed in this letter. Finally, the performance of the proposed algorithm is validated with numerical simulations. [ABSTRACT FROM AUTHOR]

Published

2020

44. Application of Multi-data Fusion Technology in Landslide Monitoring.

Author

Zhang, Xuehua, Qi, Yaolong, Xu, Jianhua, Du, Xiaoxia, Lai, Junyan, Tan, Weixian, and Huang, Pingping

Published

2020

45. Multiaperture Antenna Architecture Design for Azimuth Uniform Sampling in High-Resolution Wide-Swath SAR.

Author

Xu, Wei, Hu, Jialuo, Huang, Pingping, Tan, Weixian, and Dong, Yifan

Abstract

Azimuth multichannel synthetic aperture radar (SAR) is an essential remote sensing device to obtain images with high resolution and wide swath (HRWS). However, using a conventional multichannel phased array antenna, azimuth uniform sampling cannot be ensured, if the operated pulse repetition frequency of the system deviates from the optimum value. A novel multichannel antenna architecture design approach in HRWS SAR is proposed for uniform sampling. Phase center positions of both transmitting aperture and receiving subapertures can be adjusted flexibly by invalidating the elements of the antenna. First, a limited number of elements of receiving subapertures can be closed to adjust receive phase center spacing. The transmit phase center could be further adjusted, if the azimuth nonuniform sampling still cannot be fully compensated for. With this multiaperture antenna architecture, azimuth uniform sampling could be ensured and system performances are obviously improved. Advantages of the proposed azimuth multiaperture antenna architecture adjust method are verified by a simulation experiment. [ABSTRACT FROM AUTHOR]

Published

2020

46. Research on modelling and calculation method of river ice electromagnetic scattering.

Author

Huang, Pingping, Shi, Qiang, Tan, Weixian, Xu, Wei, and Hu, Chufeng

Subjects

ELECTROMAGNETIC waves, ICE, RADAR cross sections, MICROWAVE measurements

Abstract

In order to verify the feasibility of using microwave to study Yellow River ice, the reflected power of pure ice and mixed ice is measured by electromagnetic waves of different polarisations and frequencies in the microwave chamber. The measured data of microwave chamber measurement was processed to obtain radar cross section values. Based on the experiments in the microwave chamber, this study presents a reflection model for calculating the reflection of pure ice. The calculated value obtained by the model is consistent with the measured values, which also proves the validity of the model. The results of this study will provide some basis for the follow-up study of retrieval Yellow River ice thickness. [ABSTRACT FROM AUTHOR]

Published

2019

47. Ground-based radar data processing based on pseudo-polar coordinate system.

Author

Tan, Weixian, Li, Xiaohong, Huang, Pingping, Xu, Wei, and Hong, Wen

Subjects

TRACKING radar, ELECTROMAGNETIC waves, PULSE compression radar, SYNTHETIC aperture radar, AZIMUTH, FAST Fourier transforms

Abstract

Ground-based radar can make high-precision and real-time monitoring of micro changes in the observation area. It has been actually applied in various industries such as land, open-pit mines, water conservancy dams, and highway bridges. The basic principle of the ground-based radar is to transmit and receive electromagnetic wave signals in the distance direction and to perform pulse compression, a synthetic aperture is formed in the azimuth using the motion of the platform, and the electromagnetic wave signals are coherently accumulated to form a two-dimensional image. In this article, a fast and efficient pseudo-polar coordinate format imaging algorithm is proposed. First, in order to prevent defocusing, the authors use the Taylor approximation and the accuracy difference of the phase change due to the distance approximation is analysed. Second, the 2-D fast Fourier transform effectively achieves uniform sampling of data. The technique is validated with numerical simulations. [ABSTRACT FROM AUTHOR]

Published

2019

48. Air-borne linear frequency modulation range interrupted continuous-wave SAR for high-resolution imaging.

Author

Xu, Wei, Huang, Pingping, Tan, Weixian, Zhang, Zhenhua, Dong, Yifan, and Gao, Zhiqi

Subjects

SYNTHETIC aperture radar, CONTINUOUS wave radar, PREDICTION models, IMAGING systems, RADAR antennas

Abstract

To avoid two apertures adopted in air-borne continuous-wave (CW) synthetic aperture radar (SAR) systems, the novel air-borne linear frequency modulation range interrupted continuous wave (LFMRICW) SAR imaging mode is presented here. Different from the conventional air-borne CW imaging mode, it only requires one antenna to transmit radar pulses and receive its echoes. The system design of this mode is given in detail, and its imaging processor based on a linear prediction model (LPM) is proposed according to echo characteristics. Simulation results on distributed targets validate the presented new air-borne imaging scheme and its corresponding imaging processor. [ABSTRACT FROM AUTHOR]

Published

2019

49. Multi-source data-based method for retrieval of soil moisture in grassland.

Author

Huang, Pingping, Su, Ritu, Xu, Wei, Tan, Weixian, and Yang, Wen

Subjects

SYNTHETIC aperture radar, BACKSCATTERING, SOIL moisture, IMAGE processing, GRASSLANDS

Abstract

Taking into account the respective advantages of synthetic aperture radar (SAR) data and optical data in obtaining object information, this article presents a method for retrieval of soil moisture in grassland based on multi-source data (SAR data, optical data and measured data). First of all, optical data is used to classify the grassland area, and then the SAR data is used to obtain the backscattering coefficient of the grassland area. Finally, the soil moisture under the vegetation cover is obtained through the water-cloud model and the microwave backscatter model. The soil moisture in grassland is retrieved and the retrieval results are compared and validated using measured data. The results showed that the suggested method has better classification precision for complex terrain with densely overlapping scattering mechanisms. This method also uses the measured data to correct the soil moisture, which greatly improves the precision of the results. [ABSTRACT FROM AUTHOR]

Published

2019

50. Motion compensation method of an imaging radar based on unmanned automobile.

Author

Huang, Pingping, Shan, Wenqiu, Xu, Wei, Tan, Weixian, Dong, Yifan, and Zhang, Zhenhua

Subjects

AUTONOMOUS vehicles, AUTOMATIC systems in automobiles, MILLIMETER wave radar, REMOTELY piloted vehicles, RADAR cross sections

Abstract

Unmanned automobile will become the trend of intelligent automobile development in the future, and the application of millimetre-wave radar imaging technology is a new idea for the development of unmanned driving. Although automobile millimetre-wave radar can obtain a two-dimensional high-resolution image of the front-viewed scene, the imaging system will, however, cause the scene object to be blurred under the motion condition of the vehicle platform, which will bring difficulties to highly precise imaging. This study proposes the motion error estimation method of total least squares based on radar echo data. This method can accurately estimate the motion error and achieve motion error compensation. Finally, the validity of the method is verified through simulation experiment. [ABSTRACT FROM AUTHOR]

Published

2019