Your search keyword '"Zhou, Yashi"' showing total 13 results

1. A Radial Velocity Estimation Method of Moving Target for Azimuth Multichannel Hrws Sar

Author

Wang, Xuying, primary, Zhang, Running, additional, Wang, Zhibin, additional, and Zhou, Yashi, additional

Published

2022

2. A Novel Weight Generator in Real-Time Processing Architecture of DBF-SAR.

Author

Qiu, Jinsong, Zhang, Zhimin, Wang, Robert, Wang, Pei, Zhang, Huachun, Du, Jiang, Wang, Wei, Chen, Zhen, Zhou, Yashi, Jia, Hongying, and Sun, Huifeng

Subjects

SYNTHETIC aperture radar, SIGNAL processing, SIGNAL sampling, SPACE-based radar, SYSTEMS design, MULTICHANNEL communication

Abstract

Digital beamforming (DBF) with scan-on-receive (SCORE) technique in elevation is a powerful technique that enables a spaceborne synthetic aperture radar (SAR) to achieve high-resolution wide swath (HRWS) imaging. In the spaceborne DBF-SAR system, sampling signals from each channel are weighted by weights generated by a digital signal processing system in real-time. However, the contradiction between the shortage of spaceborne hardware resources and resource demand of the multichannel real-time signal processing increases the difficulty of system design. In order to solve this problem, a novel weight generator and an improved intermediate frequency (IF) DBF real-time processing architecture are proposed in this article. By taking advantage of the special properties of the SCORE algorithm, the proposed weight generator calculates weights using a linear polynomial algorithm. The simulation result shows that a low-order approximation can achieve high performance. The proposed generator can correct multichannel amplitude and phase error at a low cost on hardware resources. The effectiveness of the proposed method is verified by experiments with a raw data processing instance of an X-band 16 channels DBF-SAR. [ABSTRACT FROM AUTHOR]

Published

2022

3. A Novel Motion Compensation Scheme for 2-D Multichannel SAR Systems With Quaternion Posture Calculation.

Author

Chen, Zhen, Zhang, Zhimin, Qiu, Jinsong, Zhou, Yashi, Wang, Wei, Fan, Huaitao, and Wang, Robert

Subjects

SYNTHETIC aperture radar, QUATERNIONS, POSTURE, TRANSLATIONAL motion, AZIMUTH

Abstract

The displaced phase center antennas in azimuth and digital beamforming (DBF) in elevation are two state-of-the-art techniques for achieving high-resolution wide swath (HRWS) imaging in the multichannel synthetic aperture radar (SAR) systems. However, due to the atmospheric turbulence, airborne HRWS-SARs inevitably suffer trajectory disturbances, which will consequently defocus the SAR image. Although various motion compensation (MoCo) methods have been proposed, they are mostly designed for the traditional single-channel SAR and, therefore, ignore the channel-dependent posture error. The posture motion error will introduce residual motion and time-variant channel errors, which not only defocuses the image but also causes azimuth ambiguity and degrades the SNR improvement of the final images of the azimuth multichannel and DBF-SAR, respectively. To solve these problems, a novel MoCo scheme for 2-D multichannel SAR systems is proposed. The posture error is described and calculated in matrix form through the use of quaternions. Then, the posture error is transformed into the translational motion error for each receiving channel and is subsequently compensated precisely. To address the residual aperture-variant motion error, a modified aperture-dependent MoCo is integrated into the proposed scheme. Simulations and airborne experiments, including processing the data of a C-band SAR system with four azimuth channels and an X-band DBF-SAR system with 16 elevation channels, have been implemented to validate the effectiveness of the proposed MoCo scheme. [ABSTRACT FROM AUTHOR]

Published

2021

4. Digital Beamforming Synthetic Aperture Radar (DBSAR): Experiments and Performance Analysis in Support of 16-Channel Airborne X-Band SAR Data.

Author

Zhou, Yashi, Wang, Wei, Chen, Zhen, Wang, Pei, Zhang, Huachun, Qiu, Jinsong, Zhao, Qingchao, Deng, Yunkai, Zhang, Zhimin, Yu, Weidong, and Wang, Robert

Subjects

*SYNTHETIC aperture radar, *BEAMFORMING, *AIRBORNE lasers, *SIGNAL processing, *DATA warehousing, *SPACE-based radar

Abstract

In the Earth observation mission of the synthetic aperture radar (SAR), wide swath can be used to complete global monitoring in a short time and high resolution can provide rich detailed information about the feature space and prominent structure and texture. However, the traditional single-channel classical SAR system cannot meet high-resolution and wide-swath (HRWS) imaging demand due to the constraint of minimum antenna area. Fortunately, this fundamental limitation can be overcome by using multiple receive subapertures in combination with advanced digital beamforming (DBF) technique. DBF in elevation can provide high gain and better system performance and has recently gained much attention in the field of SAR imaging. This article presents a 16-channel in elevation airborne X-band DBF-SAR system with 500-MHz bandwidth, characterized by high speed data acquisition and storage, as a test bed to provide the technical reserves and support for a future spaceborne DBF-SAR system in China. The hardware configuration of this system is designed according to a realistic flight mission. To verify the feasibility and operability of this advanced 16-channel DBF-SAR system, an outfield airborne flight experiment was successfully conducted in eastern Guangdong Province in November 2019. Meanwhile, considering the inevitable channel mismatch from airborne system, a precise strategy as well as the underlying signal processing is proposed to process the experiment data. In addition to the channel mismatch due to the topographic height, the Scan-On-Receive (SCORE) pattern loss (SPL) is also an inherent factor, which will deteriorate the output SNR in final SAR images. Therefore, this article also implements a quantitative assessment of SPL combined with the practical flight parameters and the real airborne data. Finally, the corresponding processing results are presented and analyzed in detail. The practical SNR improvement of 11.23 dB emphasize that DBF technology can significantly improve the quality of SAR images and will make an essential contribution to next generation of HRWS technology for environment monitoring. [ABSTRACT FROM AUTHOR]

Published

2021

5. Implementation of a MIMO-SAR Imaging Mode Based on OFDM Chirp Waveforms.

Author

Zhang, Yongwei, Wang, Wei, Deng, Yunkai, Wang, Robert, Jin, Guodong, Zhou, Yashi, and Long, Yajun

Abstract

In this letter, a novel and low-cost echo separation technique for the multiple-input multiple-output (MIMO) synthetic aperture radar (SAR) is presented, based on the orthogonal frequency-division multiplexing (OFDM) chirp waveforms. The proposed scheme allows the generation of multiple OFDM chirp waveforms on common spectral support. In the new scheme, a series of simple time-domain operations including replica, T-shift, and superposition is applied to eliminate the interference waveform within a limited time. Then, a combination with a bandpass filter instead of a matched filter to focus signal power and digital beamforming (DBF) on receive in elevation enables the suppression of interference signals for a realistic spaceborne SAR scenario, where the swath width exceeds the spatial extension of the transmitted pulse. Furthermore, the distributed scene simulation results are presented to verify the practicability of the proposed scheme. [ABSTRACT FROM AUTHOR]

Published

2021

6. A 3.6 GHZ X-Band Wideband Experimental Airborne Sar System

Author

Zhou, Yashi, primary, Wang, Pei, additional, Ye, Kai, additional, Deng, Yunkai, additional, Wang, Robert, additional, Zhang, Huachun, additional, and Zhao, Qingchao, additional

Published

2019

7. Channel Imbalance Compensation with IF Signal for China’s IDBSAR

Author

Zhao, Qingchao, primary, Zhang, Yi, additional, Wang, Wei, additional, Wang, Pei, additional, Wang, Robert, additional, Deng, Yunkai, additional, Zhang, Huachun, additional, Ye, Kai, additional, and Zhou, Yashi, additional

Published

2019

8. High-Resolution and Wide-Swath SAR Imaging Mode Using Frequency Diverse Planar Array.

Author

Zhou, Yashi, Wang, Wei, Chen, Zhen, Zhao, Qingchao, Zhang, Heng, Deng, Yunkai, and Wang, Robert

Abstract

The challenging problem to realize high-resolution and wide-swath (HRWS) synthetic aperture radar (SAR) imaging is the ambiguity suppression in the azimuth and range directions. According to the spatial angle difference of each ambiguity component, the current technical approach is to design the spatial filter for achieving the ambiguity suppression based on the 2-D multichannel system. Along with the increasing of HRWS imaging requirements, the number of system channels also gradually increase and further result in the complex structure design of the phased array antenna system. Meanwhile, the traditional phased array antenna cannot effectively control the direction of the transmit beampattern in range. Unlike the traditional phased array, frequency diverse array (FDA) employs a small-frequency increment across the whole array elements and forms the range-angle-dependent S-shaped transmit beampattern, which can be utilized to separate the different range ambiguous region. Considering the above-mentioned characteristics and the range periodicity problem of transmit beampattern, this letter devises a scheme for spaceborne SAR HRWS imaging mode in the view of transmit beampattern utilizing 2-D planar array, i.e., the FDA in azimuth for removing the range nonperiodicity ambiguity and the conventional phased array in elevation for removing the range periodicity ambiguity. Simulation results have been presented to validate the effectiveness of the proposed scheme. [ABSTRACT FROM AUTHOR]

Published

2021

9. Elevated Frequency Diversity Array: A Novel Approach to High Resolution and Wide Swath Imaging for Synthetic Aperture Radar.

Author

Chen, Zhen, Zhang, Zhimin, Zhou, Yashi, Zhao, Qingchao, and Wang, Wei

Abstract

In this letter, we examine a new measure for high resolution and wide swath (HRWS) synthetic aperture radar (SAR) imaging based on an elevated frequency diversity array (EFDA). By highly integrating digital beamforming (DBF) and frequency diversity array (FDA) techniques, EFDA–SAR achieves range ambiguity resolution in the spatial frequency domain and range ambiguity suppression outside the observed swath in the range space domain. Moreover, the EFDA–SAR system improves the signal-to-noise ratio (SNR) due to its elevated antenna array design. A model is developed for the time-varying filtering of this novel EFDA-SAR system design. Simulation results are provided to demonstrate the efficiency of the proposed design. Using EFDA–SAR, we can obtain an HRWS SAR image without range ambiguity from the observed swath or outside it. Moreover, by combining DBF on reception, the SNR of the EFDA-SAR image is significantly improved. [ABSTRACT FROM AUTHOR]

Published

2021

10. A Novel Approach to Further Enhancing SNR in Digital Beamforming SAR Utilizing Hybrid Strip-Map/Spotlight Mode.

Author

Chen, Zhen, Zhou, Yashi, Qiu, Jinsong, Wang, Wei, Zhang, Zhimin, and Wang, Robert

Abstract

Digital beamforming (DBF) is an effective method for improving the signal-to-noise ratio (SNR) in synthetic aperture radar (SAR) images. However, further enhancing the SNR in DBF-SAR is limited by the antenna size and the expensive system cost. To address this problem, in this letter we implement a hybrid strip-map/spotlight mode for DBF. By utilizing the proposed processing method, DBF is adapted for hybrid strip-map/spotlight mode data. Furthermore, the additional synthetic aperture acquired from the hybrid strip-map/spotlight mode is employed to implement multilook processing for further enhancing the SNR of DBF-SAR images. The proposed processing method was verified by an airborne X-band 16-channel DBF-SAR system. The results confirmed that a remarkable additional SNR improvement in DBF-SAR images can be obtained using the proposed method without increasing system complexity. [ABSTRACT FROM AUTHOR]

Published

2021

11. On the Frequency Dispersion in DBF SAR and Digital Scalloped Beamforming.

Author

Zhao, Qingchao, Zhang, Yi, Wang, Wei, Liu, Kaiyu, Deng, Yunkai, Zhang, Heng, Wang, Yuying, Zhou, Yashi, and Wang, Robert

Subjects

BEAMFORMING, SYNTHETIC aperture radar, DISPERSION (Chemistry), BEAM steering, SIGNAL-to-noise ratio

Abstract

Digital beamforming (DBF) with Scan-On-Receive (SCORE) in elevation is a powerful technique for spaceborne synthetic aperture radar (SAR) to achieve high-resolution wide-swath (HRWS) images. DBF in spaceborne SAR should be implemented in real-time to reduce the volume of the downloaded data. Current digital beamformers in SAR systems usually use phase shift instead of a time delay network to ensure real-time implementation. However, conventional phase shift DBF SAR with narrow array bandwidth is not applicable for broadband signals. The beam steering deviation as a function of frequency is obvious for signals with large fractional bandwidth, which appears as a phenomenon of frequency dispersion. If the signal bandwidth is wider than the array bandwidth, frequency dispersion can significantly deteriorate the signal-to-noise ratio (SNR) and must be well relieved. This article analyzes the frequency dispersion in DBF SAR and proposes an innovative DBF-SCORE scheme with specially designed scalloped beam. The proposed digital scalloped beamforming (DSBF) scheme is effective in relieving the influence of frequency dispersion in DBF SAR. Theoretical analysis and simulation results validate the effectiveness of the proposed scheme. The proposed DSBF scheme gives practical solution to the problem of frequency dispersion in broadband DBF SAR, which makes DBF-SCORE a more practical technique for future spaceborne HRWS SAR. [ABSTRACT FROM AUTHOR]

Published

2020

12. A Novel Approach to Doppler Centroid and Channel Errors Estimation in Azimuth Multi-Channel SAR.

Author

Zhou, Yashi, Wang, Robert, Deng, Yunkai, Yu, Weidong, Fan, Huaitao, Liang, Da, and Zhao, Qingchao

Subjects

*AZIMUTH, *CHANNEL estimation, *CENTROID, *SYNTHETIC aperture radar, *ANTENNA radiation patterns, *SIGNAL-to-noise ratio, *COVARIANCE matrices, *BEAM steering

Abstract

Multi-channel synthetic aperture radar (SAR) in azimuth can overcome the minimum-antenna-area constraint of the conventional SAR in high-resolution and wide-swath (HRWS) imaging. However, the SAR system suffers from amplitude and phase mismatch among channels and nonideal antenna pattern, which will result in azimuth ambiguity and ghost targets in the final image. Therefore, taking the nonbandlimited signal and channel errors into account, a practical azimuth ambiguity-to-signal ratio (AASR) model of multi-channel SAR system is established. Meanwhile, the baseband Doppler centroid (DC) frequency related to channel errors also has an influence on image quality. Then, an effective method is proposed to calculate the baseband DC frequency according to the jumping points of the channel phase errors estimate. Subsequently, considering the effect of azimuth antenna pattern (AAP), a corresponding relationship between the ideal steering vectors and the signal subspace from the decomposing covariance matrix is established. After that, based on the uniqueness of the signal subspace and the correct corresponding relationship, an accurate method is proposed to estimate the channel phase errors by minimizing the minimum mean square error (MMSE) of the signal subspace. Finally, an accurate multi-channel SAR imaging diagram is shown to effectively mitigate the azimuth ambiguous energy caused by channel errors. Simulation and real data experiments, including four channel airborne SAR data with a bandwidth of 210 MHz and the Chinese Gaofen-3 dual receiving channel (DRC) spaceborne SAR data, validate the effectiveness of the proposed calibration method, particularly in low signal-to-noise ratio (SNR). [ABSTRACT FROM AUTHOR]

Published

2019

13. A Channel Calibration Method Based on Weighted Backprojection Algorithm for Multichannel SAR Imaging.

Author

Liang, Da, Wang, Robert, Deng, Yunkai, Fan, Huaitao, Zhang, Heng, Zhang, Lei, Wang, Wei, and Zhou, Yashi

Abstract

In the multichannel synthetic aperture radar (SAR) systems, unavoidable channel errors will significantly degrade the performance of the ambiguity suppression. To address this problem, a channel phase error estimation method is proposed in this letter. First, the multichannel echo model and the weighted backprojection algorithm are introduced. The channel phase errors are then estimated by maximizing the image intensity using the gradient descent method. The simulation results confirm that the proposed method has higher accuracy and robustness than the orthogonal subspace method. The airborne SAR data acquired by a four-channel strip map C-band airborne SAR system demonstrate the feasibility of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2019