Your search keyword '"Robert Wang"' showing total 671 results

1. Joint Narrowband RFI Suppression and Phase Synchronization Signal Retrieval for BiSAR via Robust Principal Component Analysis

Author

Yuesheng Chen, Yijiang Nan, Yonghua Cai, Pingping Lu, and Robert Wang

Subjects

Bistatic synthetic aperture radar (BiSAR), low-rank and sparsity recovery, phase synchronization, radio frequency interference (RFI), Ocean engineering, TC1501-1800, Geophysics. Cosmic physics, QC801-809

Abstract

Due to the complex electromagnetic environment and the increased demand for frequency occupation, radio frequency interference (RFI) is becoming a significant issue for the bistatic synthetic aperture radar (BiSAR), especially in the synchronization links. This article proposes a novel rank prior matrix recovery (RPMR) method based on the robust principal component analysis (RPCA) to suppress the interferences in phase synchronization of BiSAR, by which the high-accuracy synchronization phase can be acquired. First, a signal model considering the RFI in phase synchronization is proposed, proving that the synchronization signal matrix and the RFI signal matrix have the low-rank and sparsity properties in the range frequency domain, respectively. Thus, the constraint conditions of RPCA can be satisfied. Then, the RPMR method is proposed to acquire the low-rank matrix representing the synchronization signal and the sparsity matrix representing the RFI signal. In RPMR, the partial singular value decomposition utilizing the rank prior is used to replace the traditional total singular value decomposition, thus reducing the computational cost. Finally, the high-accuracy synchronization phase can be extracted from the synchronization signal by the pulse compression. Simulation and experimental results using the real measured synchronization data of LuTan-1 validate the superiority of the proposed method.

Published

2024

2. An Advanced Interferometric Baseline Estimation Method (IBEM) for Spaceborne Bistatic SAR

Author

Yanyan Zhang, Junfeng Li, Pingping Lu, and Robert Wang

Subjects

Baseline estimation, bistatic synthetic aperture radar (SAR), cross-track interferometry (XTI), LuTan-1(LT-1), Ocean engineering, TC1501-1800, Geophysics. Cosmic physics, QC801-809

Abstract

Spaceborne bistatic synthetic aperture radar (BiSAR) employs single-pass cross-track interferometry (XTI) to invert digital elevation models (DEMs) of target areas. However, the accuracy of the inverted DEM is affected by various factors, especially interferometric baseline estimation. To this end, this article proposes an advanced interferometric baseline estimation method (IBEM) for spaceborne BiSAR. First, the IBEM compensates for the time synchronization deviation of BiSAR systems using the pulse exchange phase synchronization method. Subsequently, the time, position, and velocity vectors of satellites are input into a high-precision orbit propagator to derive the state vectors at the imaging time. Leveraging these state vectors, the interferometric baseline is calculated with the main satellite that transmits radar signals as the origin of the coordinate system. Eventually, interferometric baseline estimation and DEM generation are performed based on two sets of data from the LuTan-1 (LT-1) BiSAR system, and the generated DEMs are compared with the external reference DEM to evaluate the performance of the IBEM and the LT-1 system. Results indicate that the proposed IBEM can accurately estimate the interferometric baseline and has extensive application prospects in future spaceborne multibaseline Interferometric SAR missions.

Published

2024

3. Refining Constraints on the Origin of Lunar Irregular Mare Patches via Mini-RF and DFSAR Data Analysis

Author

Fei Zhao, Yao Gao, Yanan Dang, Pingping Lu, Tingyu Meng, Tianyuan Yang, and Robert Wang

Subjects

Dual-frequency synthetic aperture radar (DFSAR), irregular mare patch (IMP), Mini-RF, synthetic aperture radar (SAR), the Moon, Ocean engineering, TC1501-1800, Geophysics. Cosmic physics, QC801-809

Abstract

Irregular mare patch (IMP) is one of the most enigmatic volcanic features in the lunar nearside maria. Their apparently fresh surface morphology and derived young model ages contradict the currently proposed thermal evolution history of the Moon. Lunar orbital synthetic aperture radar (SAR) data of Mini-RF onboard Lunar reconnaissance orbiter and dual-frequency SAR (DFSAR) flying on Chandrayaan-2 are analyzed in this article, to constrain the properties of IMPs within some depth from a radar perspective. The SAR datasets are first orthorectified and coregistered with the optical images, which allow for the interpretation of different terrains in small IMPs. Then, the polarimetric and scattering characteristics of different IMP-associated terrains are extracted and analyzed. Results show that the higher mounds in Ina, Sosigenes and Cauchy-5, as well as the lower uneven units in Ina and Sosigenes IMPs might be covered by a layer of rock-poor materials, which is similar to the surrounding maria regolith. This layer can be as thick as $>$ 0.6 m for the higher mounds and lower uneven units in Ina. Importantly, radar-bright IMPs are found, whose scattering characteristics are similar to these of the rocky units in Ina and the ejecta of degraded craters. Based on the radar characteristics of IMPs, their possible origins and evolution processes are discussed.

Published

2024

4. TEQUILA-seq: a versatile and low-cost method for targeted long-read RNA sequencing

Author

Feng Wang, Yang Xu, Robert Wang, Beatrice Zhang, Noah Smith, Amber Notaro, Samantha Gaerlan, Eric Kutschera, Kathryn E. Kadash-Edmondson, Yi Xing, and Lan Lin

Subjects

Science

Abstract

Abstract Long-read RNA sequencing (RNA-seq) is a powerful technology for transcriptome analysis, but the relatively low throughput of current long-read sequencing platforms limits transcript coverage. One strategy for overcoming this bottleneck is targeted long-read RNA-seq for preselected gene panels. We present TEQUILA-seq, a versatile, easy-to-implement, and low-cost method for targeted long-read RNA-seq utilizing isothermally linear-amplified capture probes. When performed on the Oxford nanopore platform with multiple gene panels of varying sizes, TEQUILA-seq consistently and substantially enriches transcript coverage while preserving transcript quantification. We profile full-length transcript isoforms of 468 actionable cancer genes across 40 representative breast cancer cell lines. We identify transcript isoforms enriched in specific subtypes and discover novel transcript isoforms in extensively studied cancer genes such as TP53. Among cancer genes, tumor suppressor genes (TSGs) are significantly enriched for aberrant transcript isoforms targeted for degradation via mRNA nonsense-mediated decay, revealing a common RNA-associated mechanism for TSG inactivation. TEQUILA-seq reduces the per-reaction cost of targeted capture by 2-3 orders of magnitude, as compared to a standard commercial solution. TEQUILA-seq can be broadly used for targeted sequencing of full-length transcripts in diverse biomedical research settings.

Published

2023

5. Conceptual Study and Performance Analysis of Tandem Multi-Antenna Spaceborne SAR Interferometry

Author

Fengming Hu, Feng Xu, Robert Wang, Xiaolan Qiu, Chibiao Ding, and Yaqiu Jin

Subjects

Environmental sciences, GE1-350, Physical geography, GB3-5030

Abstract

Multi-baseline synthetic aperture radar interferometry (InSAR), capable of mapping 3D surface model with high precision, is able to overcome the ill-posed problem in the single-baseline InSAR. Current tandem SAR mission utilizes a two-stage global coverage to get the dual-baseline interferograms, which achieves the trade-off between the unwrapping errors and height precision. However, the baseline adjustment will decrease the timeliness of the data acquisition, which is not suitable for monitoring temporal changes of the ground targets. Designing a SAR mission with the single-pass multi-baseline acquisition will improve the practical capability in fast 3D reconstruction. Following the asymptotic 3D phase unwrapping proposed for the airborne array InSAR system, it is possible to get a reliable 3D reconstruction using very sparse acquisitions but the interferograms should follow the optimal baseline configuration. In this article, a new concept of tandem multi-antenna SAR interferometry system for acquiring optimal single-pass multi-baseline interferograms is proposed. Two indicators, i.e., expected relative height precision and successful phase unwrapping rate, are selected to optimize the system parameters. Additionally, taking the satellites with two antennas as an example, the performances of various baseline configurations in typical scenarios and the impact of different error sources are investigated correspondingly. The simulation-based experiments demonstrate that the proposed system acquires the optimal MB interferograms for asymptotic 3D phase unwrapping, and thus enables good performance in both urban and forest area in a single flight. This system has the potential applications in accurate digital surface model acquisition, 3D target recognition, and biomass estimation.

Published

2024

6. Analysis of Rock Abundance on Lunar Surface and Near-Surface Using Mini-RF SAR Data

Author

Yao Gao, Fei Zhao, Wentao Hou, Yonghui Han, Mingliang Liu, Yanan Dang, Pingping Lu, and Robert Wang

Subjects

Circular polarization ratio (CPR), lunar regolith, miniature radio frequency (Mini-RF), rock abundance, synthetic aperture radar (SAR), Ocean engineering, TC1501-1800, Geophysics. Cosmic physics, QC801-809

Abstract

Polarimetric synthetic aperture radar (SAR) provides an effective way to understand the physical properties of planetary surfaces. Rocks are the products of specific geological events, recording the evolution of impact craters on airless bodies. Multiple-scattered radar echoes from the surface or near-surface rocks generally exhibit high circular polarization ratio (CPR). In this article, we systematically investigate the relationship between radar CPR and rock abundance of lunar regolith using miniature radio frequency (Mini-RF) SAR data. A total of 51 craters with diameters of 11.8–200 km are selected for analysis. The mean values of Mini-RF CPR and Diviner rock abundance are calculated for the interior and exterior of each crater. Statistical results show a close correlation between Mini-RF CPR and Diviner rock abundance, where high radar CPR and Diviner rock abundance are observed at the blocky ejecta. However, we find the difference of mean CPR value between crater interior and exterior is smaller than that of Diviner rock abundance. This may be attributed to the near-surface rocks that contribute to radar CPR but are not considered in the inversion of Diviner rock abundance. Therefore, the concept of volumetric rock abundance is introduced, indicating the proportion of rocks with diameters larger than one-tenth of the radar wavelength within the detection area. A three-component CPR model is then developed to link radar CPR to volumetric rock abundance. Furthermore, an inverse power-law relationship between volumetric rock abundance and crater ages is discovered, which further indicates the feasibility of using SAR data to estimate rock abundance of lunar regolith.

Published

2023

7. See-Earth: SAR Constellation with Dense Time-SEries for Multi-dimensional Environmental Monitoring of the Earth

Author

Yingjie WANG, Robert WANG, Weidong YU, Qingchao ZHAO, Kaiyu LIU, Dacheng LIU, Yunkai DENG, Naiming OU, Xiaoxue JIA, Heng ZHANG, Pengfei ZHAO, Wei WANG, Wei YU, Daqing GE, Xinming TANG, and Tao LI

Subjects

spaceborne synthetic aperture radar (sar), see-earth plan, high resolution and wide swath, polarimetric sar, high-revisit, Electricity and magnetism, QC501-766

Abstract

The limitations of satellite versatility, application dimensions, and wide-area observation efficiency are major issues impeding the development of Chinese spaceborne Synthetic Aperture Radar (SAR). China lacks a satellite system that can realize long-term, stable, and high-performance environmental dynamic monitoring oriented to the world. As the international environment becomes increasingly complex, China urgently needs to develop a SAR satellite system for global dynamic environmental monitoring to achieve large-scale, high-revisit, long-term, stable, and high-precision observations. This paper proposes a SAR Constellation with Dense Time-SEries for MultiDimensional Environmental Monitoring of the Earth (See-Earth) plan. In addition, the system conception, technical architectures, performance analysis, application potential, and new system expansion are discussed.

Published

2021

8. High-Resolution and Wide-Swath 3D Imaging for Urban Areas Based on Distributed Spaceborne SAR

Author

Yaqian Yang, Fubo Zhang, Ye Tian, Longyong Chen, Robert Wang, and Yirong Wu

Subjects

distributed spaceborne SAR, HRWS imaging, 3D reconstruction, range ambiguity resolution, Science

Abstract

Tomographic synthetic aperture radar (TomoSAR) obtains elevation resolution by adding multiple baselines successively in the direction perpendicular to the line of sight, thereby realizing three-dimensional (3D) reconstruction of complex scenes and significantly promoting the development of the 3D application field. However, a large data redundancy and long mapping time in traditional 3D imaging lead to a large data transmission burden, low efficiency, and high costs. To solve the above problems, this paper proposes a distributed SAR high-resolution and wide-swath (HRWS) 3D imaging technology scheme. The proposed scheme overcomes the size limitation of traditional single-satellite antennas through the multi-channel arrangement of multiple satellites in the elevation direction to achieve HRWS imaging; meanwhile, the distributed SAR system is integrated with tomographic processing technology to realize 3D imaging of difficult areas by using the elevation directional resolution of TomoSAR systems. HRWS 3D SAR increases the baseline length and channel number by transmission in turn, which leads to excessive pulse repetition frequency and causes echoes of different pulse signals to overlap in the same receiving cycle, resulting in range ambiguity and thus seriously affecting the quality of the 3D reconstruction. To solve this problem, this paper proposes a range ambiguity resolution algorithm based on multi-beam forming and verifies it on the measured data from airborne array SAR. Compared with the traditional TomoSAR, the distributed HRWS 3D SAR scheme proposed in this paper can obtain a greater mapping bandwidth with the same resolution in a single flight, thereby enhancing the time correlation, reducing data redundancy, and greatly improving mapping efficiency.

Published

2023

9. Performance Analysis of Channel Imbalance Control and Azimuth Ambiguity Suppression in Azimuth Dual Receiving Antenna Mode of LT-1 Spaceborne SAR System

Author

Zongxiang Xu, Pingping Lu, Yonghua Cai, Yirong Wu, and Robert Wang

Subjects

synthetic aperture radar (SAR), azimuth ambiguity suppression, high-resolution and wide-swath (HRWS), dual receive antenna (DRA), channel error estimation, Science

Abstract

The LuTan-1(LT-1), known as the L-band differential interferometric synthetic aperture radar (SAR) satellite system, is an essential piece of civil infrastructure in China, providing extensive applications such as surface deformation monitoring and topographic mapping. To achieve high-resolution and wide-swath (HRWS) observation abilities, the LT-1 takes the dual receiving antenna (DRA) imaging mode as its working mode. However, amplitude and phase errors between channels lead to a mismatch between the reconstruction filter and the multichannel echo signal, worsen the reconstructed azimuth spectrum, and introduce ambiguity targets in the final imaging results, seriously affecting the final imaging quality. In order to better evaluate the channel error and azimuth ambiguity performance of the LT-1 system, this paper proposed an advanced channel consistency correction method and conducted many measured data experiments. The experimental results show that the proposed method is effective, and the LT-1 system has excellent channel error control and azimuth ambiguity performance.

Published

2023

10. A Novel Point Target Attitude Compensation Method Using Electromagnetic Reflectance Theory

Author

Yonghui Han, Pingping Lu, Wentao Hou, Yao Gao, and Robert Wang

Subjects

polarimetric calibration, point target, synthetic aperture radar (SAR), Science

Abstract

During the process of the airborne synthetic aperture radar (SAR) system platform in space, platform attitude deflection is inevitable. However, large attitude deflection angles are unacceptable for polarimetric calibration using point targets, especially the dihedral, which is very sensitive to the pointing angle of the radar. To mitigate the impact of attitude angles on calibration accuracy, attitude compensation of the corner reflector is necessary during the calibration process. The conventional approach to attitude compensation typically maps the three-dimensional attitude angle information to the one-dimensional polarimetric orientation angle (POA) information. However, the reduction of dimension inevitably results in information loss, leading to errors that affect calibration performance when the attitude angle is large. In order to ensure the accuracy of point target calibration, this paper proposes a novel point target compensation method based on the reflection theory of electromagnetic waves. This method is based on three-dimensional attitude angle information and has higher reliability than the POA method. Finally, this paper calculates the distance between the scattering matrices obtained after compensation based on the proposed method and the POA method to obtain the difference in the performance of the two methods. Through a simulation, this paper finds that when the attitude angle is small, the results of the two schemes are approximately the same, but as the attitude angle increases, the error between the two gradually increases. This suggests that the proposed method has greater advantages in the case of attitude deflection. Furthermore, the proposed method does not require additional information supplementation compared with the equivalent POA method, making it highly practical.

Published

2023

11. An Efficient Channel Imbalance Estimation Method Based on Subadditivity of Linear Normed Space of Sub-Band Spectrum for Azimuth Multichannel SAR

Author

Zongxiang Xu, Pingping Lu, Yonghua Cai, Junfeng Li, Tianyuan Yang, Yirong Wu, and Robert Wang

Subjects

azimuth multichannel (AMC) synthetic aperture radar (SAR), high-resolution wide-swath (HRWS), channel imbalance estimation, minimizing the sum of sub-band norm (MSSBN), Science

Abstract

Azimuth multichannel (AMC) technology is one of the mainstream technical approaches to realize high-resolution wide-swath (HRWS) imaging. It has been successfully applied to several synthetic aperture radar (SAR) satellites in orbit. However, the inevitable imbalance between channels can seriously affect the azimuth reconstruction spectrum, introducing ghost targets into the final imaging results and degrading the SAR image quality. In order to address this issue, this paper proposes a channel imbalance estimation method based on minimizing the sum of the sub-band norm (MSSBN) for the reconstructed azimuth spectrum. First, the amplitude imbalance is calibrated in the range-Doppler domain. Then, the echo in each channel with phase imbalances is reconstructed by filters separately and converted to the range-Doppler domain. Finally, the global optimization algorithm is used to find the phase error of each channel so that the reconstructed postcompensation spectrum has the smallest sub-band spectrum norm sum. By two-dimensional blocking, this method can also estimate the space-varying phase imbalance in the range dimension and the time-varying phase imbalance in the azimuth dimension. Experimental results using simulated and actual AMC SAR data from the GF-3 system validate the proposed algorithm’s high estimation accuracy and excellent computational efficiency.

Published

2023

12. General Two-Stage Model-Based Three-Component Hybrid Compact Polarimetric SAR Decomposition Method

Author

Wentao Hou, Fengjun Zhao, Xiuqing Liu, and Robert Wang

Subjects

Arii volume model, hybrid compact polarimetry, model-based, polarimetric decomposition, Ocean engineering, TC1501-1800, Geophysics. Cosmic physics, QC801-809

Abstract

Polarimetric decomposition is an effective way for synthetic aperture radar (SAR) data interpretation. As for hybrid compact polarimetric (HCP) SAR, there are mainly two different types of decomposition methods, including wave-dichotomy-theorem-based and model-based. However, the existing methods are not universal because they cannot estimate volume scattering component accurately in different scenes. In order to solve this problem, a general two-stage model-based three-component HCP decomposition method (GTM) is proposed by involving Arii volume scattering model. In the first stage, a method is designed to identify the dominant scattering mechanism (surface, dihedral, and volume scattering mechanism) of each pixel according to the characteristics of the three scattering models. Then, the GTM method is solved when the three basic scattering mechanisms are dominant, respectively, in the second stage. Two simulated HCP datasets are used to verify the performance of the decomposition method. The results show that GTM can more accurately identify the dominant scattering mechanism in different regions than existing methods, and it can obtain closer results to the quad-polarimetric method.

Published

2021

13. isoCirc catalogs full-length circular RNA isoforms in human transcriptomes

Author

Ruijiao Xin, Yan Gao, Yuan Gao, Robert Wang, Kathryn E. Kadash-Edmondson, Bo Liu, Yadong Wang, Lan Lin, and Yi Xing

Subjects

Science

Abstract

Circular RNAs have been identified using short-read RNA sequencing. Here, the authors report isoCirc, a long-read sequencing method to characterize full-length circRNA isoforms and generate a catalogue of full-length circRNA isoforms in 12 human tissues and one human cell line.

Published

2021

14. Inference of single-cell phylogenies from lineage tracing data using Cassiopeia

Author

Matthew G Jones, Alex Khodaverdian, Jeffrey J Quinn, Michelle M Chan, Jeffrey A Hussmann, Robert Wang, Chenling Xu, Jonathan S Weissman, and Nir Yosef

Subjects

scRNA-seq, Single cell, Lineage tracing, CRISPR, Biology (General), QH301-705.5, Genetics, QH426-470

Abstract

Abstract The pairing of CRISPR/Cas9-based gene editing with massively parallel single-cell readouts now enables large-scale lineage tracing. However, the rapid growth in complexity of data from these assays has outpaced our ability to accurately infer phylogenetic relationships. First, we introduce Cassiopeia—a suite of scalable maximum parsimony approaches for tree reconstruction. Second, we provide a simulation framework for evaluating algorithms and exploring lineage tracer design principles. Finally, we generate the most complex experimental lineage tracing dataset to date, 34,557 human cells continuously traced over 15 generations, and use it for benchmarking phylogenetic inference approaches. We show that Cassiopeia outperforms traditional methods by several metrics and under a wide variety of parameter regimes, and provide insight into the principles for the design of improved Cas9-enabled recorders. Together, these should broadly enable large-scale mammalian lineage tracing efforts. Cassiopeia and its benchmarking resources are publicly available at www.github.com/YosefLab/Cassiopeia .

Published

2020

15. Very High Resolution SAR Imaging With DGPS-Supported Airborne X-Band Data

Author

Yashi Zhou, Pei Wang, Zhen Chen, Qingchao Zhao, Wei Wang, Lei Zhang, Weidong Yu, Yunkai Deng, and Robert Wang

Subjects

3.6 GHz full-bandwidth, high spatial resolution imaging, synthetic-aperture radar (SAR), Ocean engineering, TC1501-1800, Geophysics. Cosmic physics, QC801-809

Abstract

High spatial resolution imaging in synthetic-aperture radar (SAR) can provide accurate monitoring capacity and has been gaining great attention recently in the fields of military and civilian. Apparently, the slant range resolution of the SAR system depends on the radar operating bandwidth. Currently, the large bandwidth signal synthesizing technology of the stepped frequency chirp signal waveform is highly practical for achieving high spatial resolution. However, the system structure and the corresponding signal processing technology become more complex. In order to verify the feasibility and operability of the large full-bandwidth system, a 3.6-GHz full-bandwidth airborne experimental SAR system operating at X-band, featured by full-bandwidth transmitting and receiving, has been designed by the Department of Space Microwave Remote Sensing System, Institute of Electronics, Chinese Academy of Sciences, as a test bed for the development and implementation of the future spaceborne realizations. For this large full-bandwidth SAR system, in addition to the hardware resource, the motion compensation (MOCO) is an urgent problem. The improvement of spatial resolution will aggravate the effect of motion errors. In order to focus the SAR images accurately, this article presents a technical approach by utilizing the differential global positioning system (DGPS) technology to improve the position accuracy of the inertial measurement unit device. Meanwhile, considering the significant deviation of range cell migration correction (RCMC) due to the residual range-variant errors, this article proposes an accurate MOCO strategy with DGPS-supported to implement the second-order MOCO, space-variant residual range envelope, and space-variant residual phase error in azimuth before RCMC. Finally, this article presents the outfield experiment and reports the corresponding analysis and processing results of an outfield flight experiment successfully conducted in March 2019.

Published

2020

16. A randomized trial of icosapent ethyl in ambulatory patients with COVID-19

Author

Andrew Kosmopoulos, Deepak L. Bhatt, Gus Meglis, Raj Verma, Yi Pan, Adrian Quan, Hwee Teoh, Maya Verma, Lixia Jiao, Robert Wang, Rebecca A. Juliano, Mahesh Kajil, Mikhail N. Kosiborod, Basel Bari, Abdullahi A. Berih, Mallory Aguilar, Antonnette Escano, Andrew Leung, Idelta Coelho, Makoto Hibino, Rafael Díaz, R. Preston Mason, Ph. Gabriel Steg, Tabassome Simon, Alan S. Go, Andrew P. Ambrosy, Richard Choi, Arthur M. Kushner, Lawrence A. Leiter, Mohammed Al-Omran, Subodh Verma, and C. David Mazer

Subjects

Health sciences, Medicine, Science

Abstract

Summary: The coronavirus disease 2019 (COVID-19) pandemic remains a source of considerable morbidity and mortality throughout the world. Therapeutic options to reduce symptoms, inflammatory response, or disease progression are limited. This randomized open-label trial enrolled 100 ambulatory patients with symptomatic COVID-19 in Toronto, Canada. Results indicate that icosapent ethyl (8 g daily for 3 days followed by 4 g daily for 11 days) significantly reduced high-sensitivity C-reactive protein (hs-CRP) and improved symptomatology compared with patients assigned to usual care. Specifically, the primary biomarker endpoint, change in hs-CRP, was significantly reduced by 25% among treated patients (−0.5 mg/L, interquartile range [IQR] [−6.9,0.4], within-group p = 0.011). Conversely, a non-significant 5.6% reduction was observed among usual care patients (−0.1 mg/L, IQR [−3.2,1.7], within-group p = 0.51). An unadjusted between-group primary biomarker analysis was non-significant (p = 0.082). Overall, this report provides evidence of an early anti-inflammatory effect of icosapent ethyl in a modest sample, including an initial well-tolerated loading dose, in symptomatic outpatients with COVID-19. ClinicalTrials.gov Identifier: NCT04412018.

Published

2021

17. An Advanced Approach to Improve Synchronization Phase Accuracy with Compressive Sensing for LT-1 Bistatic Spaceborne SAR

Author

Yonghua Cai, Robert Wang, Weidong Yu, Da Liang, Kaiyu Liu, Heng Zhang, and Yafeng Chen

Subjects

bistatic synthetic aperture radar, LT-1, phase synchronization, compressive sensing, Science

Abstract

In the bistatic synthetic aperture radar (BiSAR) system, the unavoidable frequency deviation between the oscillators (USOs) will result in additional phase modulation in the demodulated radar signal, which significantly degrades the quality of the SAR image and digital elevation model (DEM) product. The innovative L-band spaceborne BiSAR system LuTan-1 (LT-1) employs a non-interrupted synchronization scheme to acquire the synchronization phase error. This advanced phase synchronization scheme avoids interrupting the normal BiSAR data acquisition and further increases the synchronization frequency. However, some non-ideal factors in the transmission link like attenuation, multipath effect, interference, etc., may cause the synchronization phase to be polluted by noise. A phase denoising approach based on compressive sensing (CS) is proposed to improve the accuracy of synchronization phase. The imaging phase with high signal-to-noise ratio (SNR) is input into the K-SVD algorithm to learn the prior information, and then the noise of the synchronization compensation phase is eliminated by maximum a posteriori (MAP) estimation. The data acquired from the ground validation system of the LT-1 synchronization module are adopted for the validation experiment. The proposed phase denoising method achieves higher phase synchronization accuracy compared with traditional ones. The processing results verify the effectiveness of the proposed method and demonstrate its potential for future on-orbit applications of the LT-1 mission.

Published

2022

18. Ultra‐wide band bowtie slot waveguide antenna array for SAR application

Author

Nan Wang, Naiming Ou, Pei Wang, and Robert Wang

Subjects

SAR application, ultra‐wide bandwidth, low‐profile waveguide antenna, antenna size, stepped square coaxial transition, ridged waveguide cavity, Telecommunication, TK5101-6720, Electricity and magnetism, QC501-766

Abstract

An ultra‐wide bandwidth, high‐efficiency, small‐size and low‐profile waveguide antenna is presented in this study. To extend the bandwidth without increasing the antenna size, the bowtie shape slot and the stepped square coaxial transition in a ridged waveguide cavity are utilised. The proposed antenna is well suited to use as an element for the phased array with the wide‐angle scanning capability, and such array is a good candidate for the synthetic aperture radar (SAR) application. The development of an active solid phased array (ASPA) utilising bowtie slot waveguide antenna as the element is presented to illustrate the design procedure. The proposed ASPA is fabricated and the measured results are provided to demonstrate that the proposed array has good performance in field pattern and impedance matching over the full X‐band (8–12 GHz). The ASPA's operating frequency band is cantered at 10 GHz with bandwidth 40%. This ASPA has been integrated into the latest SAR system with the maximum ground resolution of 0.05 m, and the SAR image is also provided at the end of this study.

Published

2019

19. A Novel Topography Retrieval Algorithm Based on Single-Pass Polarimetric SAR Data and Terrain Dependent Error Analysis

Author

Congrui Yang, Fengjun Zhao, Chunle Wang, Mengmeng Wang, Xiuqing Liu, and Robert Wang

Subjects

Lambertian model, digital elevation model (DEM), polarimetric orientation angle (POA), polarimetric synthetic aperture radar (PolSAR), terrain dependent error analysis, Science

Abstract

Polarimetric synthetic aperture radar (PolSAR) data provide an alternative way for topography retrieval, especially when limited PolSAR data are available. This article proposes a novel topography retrieval algorithm based on the Lambertian backscatter model that further improves the vertical precision of digital elevation model (DEM) generation and requires only one flight. The key idea of the proposed algorithm is to avoid data fluctuations caused by the ratio of the azimuth slope angle to the polarimetric orientation angle (POA). The previous research has confirmed the feasibility of generating a DEM based on single-pass PolSAR data, but its effect on the quality of reference DEM has not been well-explained. To analyze this effect, a large number of experiments on DEM with different resolutions are conducted. In addition, an in-depth analysis of non-linear and terrain-dependent errors is performed. The L-band PolSAR data of NASA/JPL TOPSAR and ALOS-2 PALSAR-2 and interferometric SAR (InSAR) DEM data are used to verify the proposed algorithm. The experimental results show that PolSAR data can be used as an additional reliable information source for DEM fusion under certain conditions to improve the quality of public DEM.

Published

2022

20. An Innovative Synthetic Aperture Radar Design Method for Lunar Water Ice Exploration

Author

Yanyan Zhang, Fei Zhao, Sheng Chang, Mingliang Liu, and Robert Wang

Subjects

permanently shadowed regions (PSRs), water ice, Campbell model, synthetic aperture radar (SAR), radiometric resolution, system design method, Science

Abstract

Owing to the Moon’s rough surface, there is a growing controversy over the conclusion that water ice exists in the lunar permanently shadowed regions (PSRs) with a high circular polarization ratio (CPR). To further detect water ice on the Moon, an innovative design method for spaceborne synthetic aperture radar (SAR) system is proposed, to obtain radar data that can be used to distinguish water ice from lunar regolith with a small difference in the dielectric constants. According to Campbell’s dielectric constant model and the requirement that SAR radiometric resolution is smaller than the contrast of targets in images, a newly defined SAR system function involved in the method is presented to evaluate the influence of some system parameters on the water ice detection capability of SAR. In addition, several simulation experiments are performed, and the results demonstrate that the presented SAR design method may be helpful for lunar water ice exploration.

Published

2022

21. InSAR Study of Landslides: Early Detection, Three-Dimensional, and Long-Term Surface Displacement Estimation—A Case of Xiaojiang River Basin, China

Author

Hongying Jia, Yingjie Wang, Daqing Ge, Yunkai Deng, and Robert Wang

Subjects

InSAR, landslides, early detection, 3D displacement rates, long-term time series, total least squares, Science

Abstract

Landslides, a major natural geohazard, obstruct municipal constructions and may destroy villages and towns, at worst causing significant casualties and economic losses. Interferometric Synthetic Aperture Radar (InSAR) technique offers distinct advantages on landslide detection and monitoring. In this paper, a more systematic workflow is designed for InSAR study of landslides, in terms of three levels: (i) early detection on regional scale, (ii) three-dimensional (3D) surface displacement rates estimation on detailed scale, and (iii) time series analysis on long-term temporal scale. The proposed workflow is applied for landslide research on the Xiaojiang River Basin, China, using ascending and descending Sentinel-1 images acquired from March 2017 to May 2019. First, the landslide inventory has been mapped and updated using InSAR stacking method, supporting geohazard prevention on a regional scale. A total of 22 active landslides are identified, ranging from medium to super large scale. Compared with the existing inventory, three unrecorded landslides are newly detected by our approach, and five recorded landslides are detected significant expansion of their boundaries. Then, specific to a detected landslide, Baobao landslide, a Total Least Squares–Kalman Filter-based approach is presented. Two outcomes are provided for further spatial-temporal pattern analysis: 3D displacement rates, providing an intuitive insight on the spatial characteristics and sliding direction of landslide, which are analyzed to deep the understanding of its kinematic mechanism, and long-term time series, which contribute to deduce the dynamic evolution of landslide, presenting benefits in landslide forecasting.

Published

2022

22. Hybrid Compact Polarimetric SAR Calibration Considering the Amplitude and Phase Coefficients Inconsistency

Author

Wentao Hou, Fengjun Zhao, Xiuqing Liu, Dacheng Liu, Yonghui Han, Yao Gao, and Robert Wang

Subjects

synthetic aperture radar (SAR), hybrid compact polarimetric (HCP), polarimetric calibration, amplitude and phase coefficient inconsistency, optimization, Science

Abstract

Calibration using corner reflectors is an effective way to estimate the distortion parameters of hybrid compact polarimetric (HCP) synthetic aperture radar (SAR) systems. However, the existing literature lacks a discussion on the inconsistency of the amplitude and phase coefficients between measured scattering vectors of different corner reflectors. In response to this problem, this paper first proves that this inconsistency will seriously deteriorate the estimation accuracy of polarimetric distortion parameters. Based on the optimization algorithm, two calibration schemes for simultaneously estimating the traditional distortion parameters and the amplitude/phase coefficients are proposed while ignoring crosstalk (ICT) and considering crosstalk (CCT). In the process of distortion parameter estimation, the idea of “optimizing while compensating” is adopted to eliminate the problem of uneven echo intensity. Simulation results show that both schemes can eliminate the influence of the inconsistency of amplitude and phase coefficients, and estimate distortion parameters accurately. When the received crosstalk level is lower than −30 dB, the ICT scheme can accurately estimate polarimetric distortion parameters. The CCT scheme has a wider application range of crosstalk and can work well when the crosstalk level is lower than −20 dB, but it also has a higher requirement for the signal-to-clutter ratio (SCR). When SCR is greater than 35 dB, the CCT scheme yields higher estimation accuracy than the ICT scheme. In addition, the effectiveness of the calibration schemes is verified based on the L-band measured data acquired by the Aerospace Information Research Institute, Chinese Academy of Sciences.

Published

2022

23. On the Processing of Dual-Channel Receiving Signals of the LuTan-1 SAR System

Author

Haoyu Lin, Yunkai Deng, Heng Zhang, Dacheng Liu, Da Liang, Tingzhu Fang, and Robert Wang

Subjects

synthetic aperture radar (SAR), azimuth dual-channel SAR, signal reconstruction, signal synthetic, Science

Abstract

LuTan-1 (LT-1) is an innovative spaceborne radar Earth observation mission including two satellites equipped with synthetic aperture radar (SAR) which will be launched in 2022. Active phased array antennas that can be divided into two physical channels are equipped on each satellite. The signal can be transmitted through the full antenna without broadening and recorded by each channel. Therefore, two methods can be used to preprocess the dual-channel receiving signals, referred to as dual-channel echo reconstruction and dual-channel echo synthesis. The former is inherited from the traditional high-resolution wide-swath mode and the latter is a method that takes coherent superposition as the reference. This paper researches the impacts of the two methods in system performance and imaging quality. Principles and theoretical models are firstly given. Furthermore, the system performance under the “L1A_SM_S” working mode of the LT-1 is simulated to compare the differences between the two methods, which mainly focuses on azimuth ambiguity-to-signal ratio, noise equivalent sigma zero, and the performance of block adaptive quantization. Afterwards, the test data acquired by the ground validation system of the LT-1 are used for the hardware-in-the-loop simulation to demonstrate the imaging quality between the two methods. Finally, a quantitative comparison is given.

Published

2022

24. A Novel Weighted Amplitude Modulation (WAM) System for Ambiguity Suppression of Spaceborne Hybrid Quad-Pol SAR

Author

Yanyan Zhang, Sheng Chang, Robert Wang, Peng Li, Yongwei Zhang, and Yunkai Deng

Subjects

azimuth ambiguity, weighted amplitude modulation (WAM), full-polarimetric (full-pol), synthetic aperture radar (SAR), Science

Abstract

Quadrature-polarimetric synthetic aperture radar (quad-pol SAR) has extensive applications, including climate zones classification, extraction of surface roughness, soil moisture mapping, moving target indication, and rice mapping. Hybrid quad-pol SAR ameliorates the range ambiguity performance of conventional quad-pol SAR. However, the azimuth ambiguity of its cross-polarized (cross-pol) echo signals is serious, limiting the swath width of SAR. Therefore, this paper proposes a spaceborne weighted amplitude modulation (WAM) full-polarimetric (full-pol) SAR system, and it can suppress the azimuth ambiguity of hybrid quad-pol SAR. The performance boost of the azimuth ambiguity by the two imaging modes of the proposed SAR system is detailed and evaluated with the L-band system parameters. Moreover, the chirp scaling algorithm (CSA) is adopted to execute scene simulations for the two imaging modes. The results indicate that the proposed SAR system can effectively suppress the azimuth ambiguity of hybrid quad-pol SAR and verify the theoretical analysis.

Published

2021

25. Robust boundary extraction of great lakes by blocking Active Contour Model using Chinese GF-3 SAR data: a case study of Danjiangkou reservoir, China

Author

Shilin Niu, Ning Li, Zhengwei Guo, Robert Wang, Yuexiu Guo, Lin Wu, and Jianhui Zhao

Subjects

radar imaging, remote sensing by radar, lakes, geophysical image processing, image segmentation, reservoirs, synthetic aperture radar, feature extraction, water resources, water quality, hydrological techniques, robust boundary extraction, active contour model, chinese gf-3 sar data, multipolarisation synthetic aperture radar mission, high-resolution sar image products, water source, south-to-north water diversion project, initial boundary, final water boundary, danjiangkou reservoir, chinese gaofen-3 satellite, gf-3 satellite, artificial freshwater lake, water boundary extraction, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Chinese Gaofen-3 (GF-3) satellite is a spaceborne multi-polarisation synthetic aperture radar (SAR) mission in C-band and it can be applied in the multiple fields. GF-3 can achieve accurate water boundary extraction based on its high-resolution SAR image products. This paper will study GF-3's capability to extract water boundary. Danjiangkou reservoir, the largest artificial freshwater lake in Asia and water source of Chinese South-to-North Water Diversion Project, is selected as the study region. A novel segmentation method is proposed which consists of two parts: the first part is rough segmentation to get the initial boundary; the second part is fine segmentation to get the final water boundary. Experimental results show that GF-3 has good performance in water boundary exaction by virtue of this novel method.

Published

2019

26. Ionospheric correction of ALOS-2 full-aperture ScanSAR interferometric data for surface deformation measurement in Beijing

Author

Jiaqi Ning, Robert Wang, Jili Wang, Bowen Zhang, and Shuang Zhao

Subjects

spaceborne radar, ionospheric disturbances, radar imaging, synthetic aperture radar, radar interferometry, ionospheric techniques, ionospheric correction, surface deformation measurement, Beijing, spaceborne SAR systems, low frequency, L-band, imaging modes, ScanSAR mode, ionospheric disturbance phase screen, full-aperture ScanSAR images, October 2016, split range-spectrum technique, differential interferograms, ionospheric extraction, nonlocal filtering, spatial deformation distribution, differential interferometric synthetic aperture radar technique, D-InSAR, ALOS-2 ScanSAR images, persistent scatterer interferometric synthetic aperture radar technique, PS-InSAR, Sentinel Tops mode images, October 2015–February, ionospheric distortion extraction method, deformation trend, geographical information, ground deformation, ALOS-2 full-aperture ScanSAR interferometric data, AD 2015 10 to 2017 02, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Ionospheric disturbance is one of the most serious factors that limit the accuracy of deformation measurement of interferometric synthetic aperture radar (InSAR) especially for spaceborne SAR systems in low frequency such as L-band. Especially in imaging modes with a large coverage, ScanSAR mode for example, ionospheric disturbance phase screen almost submerges other useful geographical information. In this study, two ALOS-2 (L-band) full-aperture ScanSAR images (October 2015 and October 2016) are used to study ground deformation in Beijing from 2015 to 2016. The split range-spectrum technique is adopted to extract ionospheric distortion. The authors splice the differential interferograms of adjacent subswaths by resampling them to perform the overall ionospheric extraction. Also non-local filtering is used to improve the coherence of interferograms. Spatial deformation distribution that was obtained by differential interferometric synthetic aperture radar (D-InSAR) technique using the two ALOS-2 ScanSAR images is highly consistent with the result obtained by persistent scatterer interferometric synthetic aperture radar (PS-InSAR) technique using Sentinel Tops mode images (October 2015–February 2017). The comparison results show the effectiveness of the ionospheric distortion extraction method used in this study. Moreover, the spatial distribution is also highly consistent with the results before 2014, which means that the deformation trend in Beijing continues.

Published

2019

27. Going Deeper in Spiking Neural Networks: VGG and Residual Architectures

Author

Abhronil Sengupta, Yuting Ye, Robert Wang, Chiao Liu, and Kaushik Roy

Subjects

spiking neural networks, event-driven neural networks, sparsity, neuromorphic computing, visual recognition, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Over the past few years, Spiking Neural Networks (SNNs) have become popular as a possible pathway to enable low-power event-driven neuromorphic hardware. However, their application in machine learning have largely been limited to very shallow neural network architectures for simple problems. In this paper, we propose a novel algorithmic technique for generating an SNN with a deep architecture, and demonstrate its effectiveness on complex visual recognition problems such as CIFAR-10 and ImageNet. Our technique applies to both VGG and Residual network architectures, with significantly better accuracy than the state-of-the-art. Finally, we present analysis of the sparse event-driven computations to demonstrate reduced hardware overhead when operating in the spiking domain.

Published

2019

28. Ambiguity Suppression Based on Joint Optimization for Multichannel Hybrid and ±π/4 Quad-Pol SAR Systems

Author

Pengfei Zhao, Yunkai Deng, Wei Wang, Yongwei Zhang, and Robert Wang

Subjects

azimuth ambiguities, azimuth multichannel, joint optimization, quadrature-polarimetric (quad-pol), synthetic aperture radar (SAR), Science

Abstract

Hybrid and ±π/4 quadrature-polarimetric (quad-pol) synthetic aperture radar (SAR) systems operating from space can obtain all polarimetric components simultaneously but suffer from severe azimuth ambiguities in the cross-polarized (cross-pol) measurement channels. In this paper, the hybrid and ±π/4 quad-pol SAR systems with multiple receive channels in azimuth are widely investigated to suppress the azimuth ambiguities of the cross-pol components. We first provide a more thorough analysis of the multichannel hybrid and ±π/4 quad-pol SAR systems. Then, the multichannel signal processing is briefly discussed for the reconstruction of the quad-pol SAR signal from the aliased signals, in which the conventional reconstruction algorithm causes extremely severe azimuth ambiguities. To this end, an improved reconstruction method is proposed based on a joint optimization, which allows for the minimization of ambiguities from the desired polarization and the simultaneous power of undesired polarized signal. This method can largely suppress azimuth ambiguities compared with the conventional reconstruction algorithm. Finally, to verify the advantages and effectiveness of the proposed approach, the azimuth ambiguity-to-signal ratio (AASR), the range ambiguity-to-signal ratio (RASR) and signal-to-noise ratio (SNR) of all polarizations, as well as a set of imaging simulation results, are given to describe the effects of reconstruction on the multichannel hybrid and ±π/4 quad-pol SAR systems.

Published

2021

29. Characteristics of Saline Soil in Extremely Arid Regions: A Case Study Using GF-3 and ALOS-2 Quad-Pol SAR Data in Qinghai, China

Author

Yao Gao, Xiuqing Liu, Wentao Hou, Yonghui Han, Robert Wang, and Heng Zhang

Subjects

soil salinity, synthetic aperture radar (SAR), polarimetric, dielectric constant, integral equation model (IEM), Science

Abstract

Soil salinization is a global problem, which seriously damages the ecological environment and considerably reduces agricultural productivity, especially in arid regions. Synthetic aperture radar (SAR) has been widely used in remote sensing due to its weather and sunlight independence. Polarimetric SAR has great potential for large-scale mapping and monitoring salt-affected soils. In this study, we investigate the characteristics of saline soil in extremely arid regions using dual-band quadrature-polarimetric (quad-pol) SAR images acquired by GF-3 (C-band) and ALOS-2 (L-band). Firstly, the effectiveness of the modified dielectric mixing model and integral equation model (IEM) in describing saline soil is evaluated. Secondly, the potential relationships between polarimetric parameters and salinity are discussed in both the C- and L-band, respectively, such as co-polarization ratio, scattering entropy H, and scattering angle α. Finally, a linear regression model for monitoring salt content is established. The main contributions of this article are as follows: (1) Simulation results suggest that the radar backscattering coefficient is a weak function of salinity at low water content, but our experimental data show that soil salinity significantly contributes to the radar backscattering coefficient, which indicates the modified dielectric mixing model and IEM model is not applicable in extremely arid areas. (2) A negative correlation between the co-polarization ratio and salinity is observed, and the correlation coefficients are 0.64 (C-band) and 0.71 (L-band). Besides, scattering entropy and scattering angle exhibit a positive correlation with salinity in the C-band with correlation coefficients 0.686 and 0.669, respectively, whereas a negative correlation is found in the L-band with correlation coefficients 0.682 and 0.680, respectively. This can be attributed to the different penetration depths and sensitivity to the surface roughness of the electromagnetic waves at two frequencies. (3) A regression model for salinity estimating based on radar backscattering coefficient, co-polarization ratio, and scattering entropy is established, with a determination coefficient (R2) of 0.79 and a root mean square error (RMSE) of 6.56%, allowing us to determine soil salinity from quad-pol SAR images without using backscattering models. Therefore, our results can be a reference for future soil salinity monitoring and inversion.

Published

2021

30. Rethinking the Random Cropping Data Augmentation Method Used in the Training of CNN-Based SAR Image Ship Detector

Author

Rong Yang, Robert Wang, Yunkai Deng, Xiaoxue Jia, and Heng Zhang

Subjects

CNN, data augmentation, SAR, ship detection, Science

Abstract

The random cropping data augmentation method is widely used to train convolutional neural network (CNN)-based target detectors to detect targets in optical images (e.g., COCO datasets). It can expand the scale of the dataset dozens of times while consuming only a small amount of calculations when training the neural network detector. In addition, random cropping can also greatly enhance the spatial robustness of the model, because it can make the same target appear in different positions of the sample image. Nowadays, random cropping and random flipping have become the standard configuration for those tasks with limited training data, which makes it natural to introduce them into the training of CNN-based synthetic aperture radar (SAR) image ship detectors. However, in this paper, we show that the introduction of traditional random cropping methods directly in the training of the CNN-based SAR image ship detector may generate a lot of noise in the gradient during back propagation, which hurts the detection performance. In order to eliminate the noise in the training gradient, a simple and effective training method based on feature map mask is proposed. Experiments prove that the proposed method can effectively eliminate the gradient noise introduced by random cropping and significantly improve the detection performance under a variety of evaluation indicators without increasing inference cost.

Published

2020

31. Implementation of a Phase Synchronization Scheme Based on Pulsed Signal at Carrier Frequency for Bistatic SAR

Author

Yafeng Chen, Da Liang, Haixia Yue, Dacheng Liu, Xiayi Wu, Heng Zhang, Yuanbo Jiao, Kaiyu Liu, and Robert Wang

Subjects

phase synchronization, pulsed signal, carrier frequency, bistatic SAR, Chemical technology, TP1-1185

Abstract

Phase synchronization is one of the key technical challenges and prerequisites for the bistatic synthetic aperture radar (SAR) system, which can form a single-pass interferometry system to perform topographic mapping. In this paper, an advanced phase synchronization scheme based on a pulsed signal at carrier frequency is proposed for a bistatic SAR system and it is verified by a ground validation system. In the proposed phase synchronization scheme, the pulsed signal at carrier frequency is used for phase synchronization link, and it is exchanged by virtue of a time slot between radar signals. The feasibility of the scheme is proven by theoretical analysis of various factors affecting the performance of phase synchronization, and the reliability of the scheme is verified by the test results of the ground validation system.

Published

2020

32. Azimuth Ambiguity Suppression for Hybrid Polarimetric Synthetic Aperture Radar via Waveform Diversity

Author

Pengfei Zhao, Yunkai Deng, Wei Wang, Dacheng Liu, and Robert Wang

Subjects

azimuth ambiguities, dual-focus post-processing (DFPP), hybrid quadrature polarization (hybrid quad-pol), synthetic aperture radar (SAR), waveform diversity, Science

Abstract

Hybrid quadrature polarimetric (hybrid quad-pol) synthetic aperture radar (SAR) is proposed as a potential candidate for the full-polarimetric SAR mode. It allows balanced range ambiguity performance and simplified system structure. System based on hybrid-pol SAR mode can also implement the conventional quad-pol mode and the compact-pol mode via few adjustments. However, the azimuth ambiguity performance in cross-pol channels is proved deteriorated in hybrid quad-pol mode due to the lopsided energy distribution of ambiguities. As are generally called “ghost” targets, azimuth ambiguities usually influence the recognition of the targets in SAR imaging. This letter describes how to remove the false targets that arise from azimuth ambiguities by means of waveform diversity and dual-focus post-processing (DFPP) technique. The proposed method exploits the feature of azimuth ambiguity and yields improved image quality in cross-pol channels with strong co-pol azimuth ambiguities removed in hybrid quad-pol SAR at a low system cost. Furthermore, it offers remarkable benefits for target detecting and recognition with strong false targets removed.

Published

2020

33. The Synchronization Transceiver Design and Experimental Verification for the LuTan-1 SAR Satellite

Author

Yuanbo Jiao, Da Liang, Kaiyu Liu, Yafeng Chen, Huaizu Wang, and Robert Wang

Subjects

bistatic synthetic aperture radar (bisar), phase synchronization, non-interrupted, synchronization transceiver (str), Chemical technology, TP1-1185

Abstract

The deviation between the two oscillators in BiSAR systems will cause a residual modulation of echo signal. Therefore, the phase synchronization is an important issue that must be addressed for BiSAR systems. An advanced non-interrupted phase synchronization scheme is used for the LuTan-1 SAR satellite. The synchronization transceiver (STR) is designed for transmitting and receiving synchronization signals. In addition, STR mainly consists of master and auxiliary transceivers and switch module. Furthermore, the function and working principle of STR are introduced, and the detailed design of each part is described. The measured results are also evaluated to prove the performance of the STR. In addition, the phase synchronization accuracy is also demonstrated to verify the effectiveness of the non-interrupted synchronization scheme. The standard deviation (STD) of the residual phase is less than 0.3 degrees. The results have guiding significance for the synchronization unit design of LuTan-1 and the future BiSAR system.

Published

2020

34. Exploration of Advanced Bistatic SAR Experiments (in English)

Author

Deng Yun-kai and Robert Wang

Subjects

istatic Synthetic Aperture Radar (BiSAR), Multiple Baseline Interferometry SAR (MB-InSAR), Digital BeamForming (DBF), TerraSAR, PAMIR, Electricity and magnetism, QC501-766

Abstract

This study concentrates on the results of several advanced hybrid bistatic SAR experiments. The hybrid bistatic configuration applies to the case in which the transmitter and receiver are mounted on different types of platforms, e.g., spaceborne/airborne, airborne/stationary, spaceborne/stationary, and so on. Several hybrid bistatic SAR experiments have been performed successfully, i.e., TerraSAR-X/PAMIR, PAMIR/stationary, and TerraSAR-X/stationary. Furthermore, Multiple Baseline Interferometry SAR (MB-InSAR) and Digital Beam-Forming (DBF) technologies are validated in the TerraSAR-X/stationary configuration. Note that the DBF experiment results based on the spaceborne illuminator are discussed for the first time in SAR community. In addition, this paper emphasizes imaging geometry, image analysis, and focusing results.

Published

2014

35. TouchInsight: Uncertainty-aware Rapid Touch and Text Input for Mixed Reality from Egocentric Vision.

Author

Paul Streli, Mark Richardson, Fadi Botros, Shugao Ma, Robert Wang 0002, and Christian Holz 0001

Published

2024

36. StegoType: Surface Typing from Egocentric Cameras.

Author

Mark Richardson, Fadi Botros, Yangyang Shi, Pinhao Guo, Bradford J. Snow, Linguang Zhang, Jingming Dong, Keith Vertanen, Shugao Ma, and Robert Wang 0002

Published

2024

37. Monitoring Landslides along the Jinsha River Basin Based on Dempster-Shafer Evidence Theory with Multi-Source INSAR Time Series.

Author

Qingyue Yang, Zhang Yunjun, Yidi Wang, Yosuke Aoki, and Robert Wang 0001

Published

2024

38. Preliminary Results of Raw DEM of LuTan-1 Bistatic SAR.

Author

Yachao Wang, Zekun Jiao, Jingwen Mou, Yonghua Cai, Bingnan Wang, Aichun Wang, and Robert Wang 0001

Published

2024

39. STMG: A Machine Learning Microgesture Recognition System for Supporting Thumb-Based VR/AR Input.

Author

Kenrick Kin, Chengde Wan, Ken Koh, Andrei Marin, Necati Cihan Camgöz, Yubo Zhang, Yujun Cai, Fedor Kovalev, Moshe Ben-Zacharia, Shannon Hoople, Marcos Nunes-Ueno, Mariel Sanchez-Rodriguez, Ayush Bhargava, Robert Wang 0002, Eric Sauser, and Shugao Ma

Published

2024

40. Fast Algorithms for Directed Graph Partitioning Using Flows and Reweighted Eigenvalues.

Author

Lap Chi Lau, Kam Chuen Tung, and Robert Wang 0004

Published

2024

41. Research on Strong Clutter Suppression for Gaofen-3 Dual-Channel SAR/GMTI

Author

Mingjie Zheng, He Yan, Lei Zhang, Weidong Yu, Yunkai Deng, and Robert Wang

Subjects

Gaofen-3, SAR/GMTI, clutter suppression, error correction, Chemical technology, TP1-1185

Abstract

In spaceborne synthetic aperture radar (SAR), moving targets are almost buried in ground clutter due to the wide clutter Doppler spectrum and the restricted pulse repetition frequency (PRF), which increases the difficulty of moving target detection. Clutter suppression is one of the key issues in the spaceborne SAR moving target indicator operation. In this paper, we describe the clutter suppression principle and analyze the influence of amplitude and phase error on clutter suppression. In the following, a novel dual-channel SAR clutter suppression algorithm is proposed, which is suitable for the Gaofen-3(GF-3) SAR sensor. The proposed algorithm consists of three technique steps, namely adaptive two-dimensional (2D) channel calibration, refined amplitude error correction and refined phase error correction. After channel error is corrected by these procedures, the clutter component, especially a strong clutter component, can be well suppressed. The validity of the proposed algorithm is verified by GF-3 SAR real data which demonstrates the ground moving-target indication (GMTI) capability of GF-3 SAR sensor.

Published

2018

42. An Accelerated Backprojection Algorithm for Monostatic and Bistatic SAR Processing

Author

Heng Zhang, Jiangwen Tang, Robert Wang, Yunkai Deng, Wei Wang, and Ning Li

Subjects

accelerated backprojection algorithm, bistatic SAR, monostatic SAR, bulk processing, Science

Abstract

The backprojection (BP) algorithm has been applied to every SAR mode due to its great focusing quality and adaptability. However, the BP algorithm suffers from immense computational complexity. To improve the efficiency of the conventional BP algorithm, several fast BP (FBP) algorithms, such as the fast factorization BP (FFBP) and Block_FFBP, have been developed in recent studies. In the derivation of Block_FFBP, range data are divided into blocks, and the upsampling process is performed using an interpolation kernel instead of a fast Fourier transform (FFT), which reduces the processing efficiency. To circumvent these limitations, an accelerated BP algorithm based on Block_FFBP is proposed. In this algorithm, a fixed number of pivots rather than the beam centers is applied to construct the relationship of the propagation time delay between the “new” and “old” subapertures. Partition in the range dimension is avoided, and the range data are processed as a bulk. This accelerated BP algorithm benefits from the integrated range processing scheme and is extended to bistatic SAR processing. In this sense, the proposed algorithm can be referred to simply as MoBulk_FFBP for the monostatic SAR case and BiBulk_FFBP for the bistatic SAR case. Furthermore, for monostatic and azimuth-invariant bistatic SAR cases where the platform runs along a straight trajectory, the slant range mapping can be expressed in a continuous and analytical form. Real data from the spaceborne/stationary bistatic SAR experiment with TerraSAR-X operating in the staring spotlight mode and from the airborne spotlight SAR experiment acquired in 2016 are used to validate the performances of BiBulk_FFBP and MoBulk_FFBP, respectively.

Published

2018

43. Correction of Channel Imbalance for MIMO SAR Using Stepped-Frequency Chirps

Author

Xiulian Luo, Yunkai Deng, Robert Wang, Lei Guo, and Mingjiang Wang

Subjects

Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Cellular telephone services industry. Wireless telephone industry, HE9713-9715

Abstract

To simultaneously achieve two-dimensional high resolution and wide swath in synthetic aperture radar (SAR), azimuth MIMO structure combined with stepped-frequency chirp signals was developed via splitting the antenna into N subapertures. During transmitting each subaperture transmits a chirp pulse at a different carrier frequency, while during receiving every subaperture receives the N scattered pulses at the same time. Separating the N scattered pulses received by each subaperture and downlinking them to the ground yield N2 different signal paths. Due to the dedicated network in the SAR system, the channel imbalance is inevitable. To correct the channel imbalance, this paper presents an external calibration method, where the channel characteristics are estimated from the peak value of a strong point target for each channel. Simulation and real raw data experiments are performed to validate the proposed method.

Published

2014

44. Channel Phase Error Compensation for MIMO-SAR

Author

Lei Zhang, Yunkai Deng, and Robert Wang

Subjects

Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Cellular telephone services industry. Wireless telephone industry, HE9713-9715

Abstract

Multi-input multioutput (MIMO) is a novel technique to achieve high-resolution as well as wide swath in synthetic aperture radar (SAR) systems. Channel imbalance is inevitable in multichannel systems that it declines the imaging quality. Generally, the imbalance cannot be fully compensated by simple internal calibration in a MIMO-SAR system. In this paper, a new algorithm based on raw data is presented to remove the channel phase error. Based on the error source, this approach models the phase error as two parts: the transmit phase error and the receive phase error. The receive phase error is removed using cost function at the azimuth processing stage, whereas the transmit phase error is estimated with correlation. Point target simulations confirm the influence of channel phase error and the validation of the proposed approach. Besides, the performance is also investigated.

Published

2014

45. A Spaceborne Wide-Area Surveillance Mode and Its Application in Maritime Monitoring

Author

Shi-Chao Zheng, Hong-Jun Song, Robert Wang, Yun-Hua Luo, and Kun Wu

Subjects

Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Cellular telephone services industry. Wireless telephone industry, HE9713-9715

Abstract

The spaceborne wide-area surveillance mode, achieved by a modified TOPSAR mode, is proposed for maritime monitoring. In the proposed mode, the requirements of detecting targets from different aspect angles with a high revisit rate can be satisfied by modifying the TOPSAR mode which steers antenna in the azimuth direction. The feasibility as well as its application in maritime monitoring are validated by theoretical analysis and simulation experiments.

Published

2013

46. Integrated Time and Phase Synchronization Strategy for a Multichannel Spaceborne-Stationary Bistatic SAR System

Author

Feng Hong, Robert Wang, Zhimin Zhang, Pingping Lu, and Timo Balz

Subjects

bistatic SAR, time synchronization, phase synchronization, Back Projection Algorithm (BPA), Science

Abstract

The spatial separation of the transmitter and receiver in Bistatic Synthetic Aperture Radar (BiSAR) makes it a promising and useful supplement to a classical Monostatic SAR system (MonoSAR). This paper proposes a novel integrated time and phase synchronization strategy for a multichannel spaceborne-stationary BiSAR system. Firstly, the time synchronization strategy is proposed, which includes Pulse Repetition Frequency (PRF) generation under noisy conditions, multichannel calibration and the alignment of the recorded data with the orbital data. Furthermore, the phase synchronization strategy, which fully considers the deteriorative factors in the BiSAR configuration, is well studied. The contribution of the phase synchronization strategy includes two aspects: it not only compensates the phase error, but also improves the Signal to Noise Ratio (SNR) of the obtained signals. Specifically, all direct signals on different PRF time can be reconstructed with the shift and phase compensation operation using a reference signal. Besides, since the parameters of the reference signal can be estimated only once using the selected practical direct signal and a priori information, the processing complexity is well reduced. Final imaging results with and without compensation for real data are presented to validate the proposed synchronization strategy.

Published

2016

47. MotionDeltaCNN: Sparse CNN Inference of Frame Differences in Moving Camera Videos with Spherical Buffers and Padded Convolutions.

Author

Mathias Parger, Chengcheng Tang, Thomas Neff, Christopher D. Twigg, Cem Keskin, Robert Wang 0002, and Markus Steinberger

Published

2023

48. Cheeger Inequalities for Directed Graphs and Hypergraphs using Reweighted Eigenvalues.

Author

Lap Chi Lau, Kam Chuen Tung, and Robert Wang 0004

Published

2023

49. Experimental Design for Any p-Norm.

Author

Lap Chi Lau, Robert Wang 0004, and Hong Zhou 0001

Published

2023

50. InSAR Tropospheric Delay Correction for Wide-Area Deformation Identification and Monitoring.

Author

Qingyue Yang, Zhang Yunjun, Yonghua Cai, Pingping Lu, and Robert Wang 0001

Published

2023