DISPLACED PHASE CENTER ANTENNA SAR IMAGING BASED ON COMPRESSED SENSING Yueguan Lin 1,2,3, Bingchen Zhang 1,2, Wen Hong 1,2 and Yirong Wu 1,2 1 National.

Slides:

Advertisements

Similar presentations

Junzhou Huang, Shaoting Zhang, Dimitris Metaxas CBIM, Dept. Computer Science, Rutgers University Efficient MR Image Reconstruction for Compressed MR Imaging.

Advertisements

Compressive Data Gathering for Large-Scale Wireless Sensor Networks

Digital Coding of Analog Signal Prepared By: Amit Degada Teaching Assistant Electronics Engineering Department, Sardar Vallabhbhai National Institute of.

IGARSS 2011, July , Vancouver, Canada Demonstration of Target Vibration Estimation in Synthetic Aperture Radar Imagery Qi Wang 1,2, Matthew Pepin.

On Estimation of Soil Moisture & Snow Properties with SAR Jiancheng Shi Institute for Computational Earth System Science University of California, Santa.

M. Younis Design Optimization Aspects for Reflector Base Synthetic Aperture Radar Marwan Younis, Anton Patyuchenko, Sigurd Huber, and Gerhard Krieger,

DPSS Radar Research Topics 2 December 2010 Leon Staphorst Principle Researcher Radar and Electronic Warfare Defence, Peace, Safety and Security.

Folie 1 Ambiguity Suppression by Azimuth Phase Coding in Multichannel SAR Systems DLR - Institut für Hochfrequenztechnik und Radarsysteme F. Bordoni, M.

Folie 1 Performance Investigation on the High-Resolution Wide-Swath SAR System Operating in Stripmap Quad-Pol and Ultra-Wide ScanSAR Mode DLR - Institut.

Compressed Sensing in MIMO Radar Chun-Yang Chen and P. P. Vaidyanathan California Institute of Technology Electrical Engineering/DSP Lab Asilomar 2008.

Remote Sensing Technology Institute Extraction of the surface velocity of rivers with SAR- ATI H. Runge 1, S. Suchandt 1, R. Horn 2, T. Eiglsperger 3 German.

Sunzi Theorem and Signal Processing Xiang-Gen Xia Dept. of Electrical & Computer Engineering University of Delaware Newark, DE 19716

Problem: Ground Clutter Clutter: There is always clutter in signals and it distorts the purposeful component of the signal. Getting rid of clutter, or.

Radar: Acronym for Radio Detection and Ranging

Doppler Radar From Josh Wurman NCAR S-POL DOPPLER RADAR.

Synthetic-Aperture Radar (SAR) Image Formation Processing

Tutorial I: Radar Introduction and basic concepts

Development of Focusing Algorithms for Arc-scanning Ground-Based Synthetic Aperture Radar Hoonyol Lee Dept. of Geophysics, Kangwon National University.

Competence Centre on Information Extraction and Image Understanding for Earth Observation Matteo Soccorsi (1) and Mihai Datcu (1,2) A Complex GMRF for.

Efficient design of a C-band aperture-coupled stacked microstrip array using Nexxim and Designer Alberto Di Maria German Aerospace Centre (DLR) – Microwaves.

Compressed Sensing Based UWB System Peng Zhang Wireless Networking System Lab WiNSys.

Imaging results from monostatic and bistatic radar observations of the Moon made at a wavelength of 68 cm (440.2 MHz) with the Millstone MISA radar transceiving.

Compressive Sensing Based on Local Regional Data in Wireless Sensor Networks Hao Yang, Liusheng Huang, Hongli Xu, Wei Yang 2012 IEEE Wireless Communications.

Dr A VENGADARAJAN, Sc ‘F’, LRDE

Cs: compressed sensing

Junjie Wu, Jianyu Yang, et.al. Univ. of Electro. Sci. & Tech. of China

Ping Zhang, Zhen Li,Jianmin Zhou, Quan Chen, Bangsen Tian

1 LV Distribution, Performance and Applications Presented by: Bi Guoan School of Electrical and Electronic Engineering Nanyang Technological University.

The principle of SAMI and some results in MAST 1. Institute of Plasma Physics, Chinese Academy of Sciences, Hefei, Anhui, , China 2. Culham Centre.

Jul. 29, 2011IGARSS [3118] RELATION BETWEEN ROCK FAILURE MICROWAVE SIGNALS DETECTED BY AMSR-E AND A DISTRIBUTION OF RUPTURES GENERATED BY SEISMIC.

Radar Project Pulse Compression Radar

Radar Signals Tutorial II: The Ambiguity Function

SWOT Near Nadir Ka-band SAR Interferometry: SWOT Airborne Experiment Xiaoqing Wu, JPL, California Institute of Technology, USA Scott Hensley, JPL, California.

A Measuring Polygon with a Complex of Polarimetric, Combined Active-Passive Sensors of S-, Ku-, and Ka-band of Frequencies for Soil and Snow Remote Sensing.

1 Abstract - KNU and KIGAM are developing a ground-based Arc-scanning SAR system (ArcSAR) mounted on a truck. The system achieves a coherent integration.

1 Nonlinear Range Cell Migration (RCM) Compensation Method for Spaceborne/Airborne Forward-Looking Bistatic SAR Nonlinear Range Cell Migration (RCM) Compensation.

Azimuthal SAR Interferogram (azisar) Sylvain Barbot, Institute of Geophysics and Planetary Sciences, Scripps Institution of Oceanography, University of.

SAR Algorithms For the few classes, we are going to look at some efficient ways to implement SAR processing. But before we do this, I want to draw your.

Doc.: IEEE /270 Submission July 2003 Liang Li, Helicomm Inc.Slide 1 Project: IEEE P Working Group for Wireless Personal Area Networks (WPANs)

Competence Centre on Information Extraction and Image Understanding for Earth Observation 1 High Resolution Complex SAR Image Analysis Using Azimuth Sub-Band.

MITSUBISHI ELECTRIC RESEARCH LABORATORIES Cambridge, Massachusetts High resolution SAR imaging using random pulse timing Dehong Liu IGARSS’ 2011 Vancouver,

A DISTRIBUTION BASED VIDEO REPRESENTATION FOR HUMAN ACTION RECOGNITION Yan Song, Sheng Tang, Yan-Tao Zheng, Tat-Seng Chua, Yongdong Zhang, Shouxun Lin.

A WEIGHTED CALIBRATION METHOD OF INTERFEROMETRIC SAR DATA Yongfei Mao Maosheng Xiang Lideng Wei Daojing Li Bingchen Zhang Institute of Electronics, Chinese.

PARALLEL FREQUENCY RADAR VIA COMPRESSIVE SENSING

University of Electronic Science and Technology of China

Review Doppler Radar (Fig. 3.1) A simplified block diagram 10/29-11/11/2013METR

Sponsored By Abstract 1 Ritamar Siurano – Undergraduate Student Prof. Domingo Rodriguez – Advisor Abigail Fuentes – Graduate StudentProf. Ana B. Ramirez.

Sponsored By Abstract 1 Ritamar Siurano – Undergraduate Student Prof. Domingo Rodriguez – Advisor Abigail Fuentes – Graduate Student Prof. Ana B. Ramirez.

CHARACTERIZATION PRESENTATION ANAT KLEMPNER SPRING 2012 SUPERVISED BY: MALISA MARIJAN YONINA ELDAR A Compressed Sensing Based UWB Communication System.

Classification Method Validation for Rice Mapping Using ENVISAT APS Data Erxue CHEN(1), Zengyuan LI(1), BingxiangTan(1) ， Wei He(1), Bingbai LI(2) (1)Institute.

Chongwen DUAN, Weidong HU, Xiaoyong DU ATR Key Laboratory, National University of Defense Technology IGARSS 2011, Vancouver.

Performance Issues in Doppler Ultrasound 1. 2 Fundamental Tradeoffs In pulsed modes (PW and color), maximum velocity without aliasing is In pulsed modes,

Imaging Radars: system architectures and technologies G. Angino, A. Torre Frascati, INFN, 2011, November 28th.

Date of download: 7/7/2016 Copyright © 2016 SPIE. All rights reserved. Evaluation of the orthogonal matching pursuit (OMP) cost over the target space in.

Correlating Synthetic Aperture Radar (CoSAR) DIVYA CHALLA.

Meng Liu,Hong Zhang,Chao Wang, Bo Zhang

Environmental and Disaster Monitoring Small Satellite Constellation

Bag-of-Visual-Words Based Feature Extraction

Efficient Estimation of Residual Trajectory Deviations from SAR data

IGRASS2011 An Interferometric Coherence Optimization Method Based on Genetic Algorithm in PolInSAR Peifeng Ma, Hong Zhang, Chao Wang, Jiehong Chen Center.

Developed by Eastwood Im Jet Propulsion Laboratory

Open book, open notes, bring a calculator

Another Cambridge physicist... Bounces man-made radar waves off target

Chap II. Radar Hardware (PART 1)

A KU-BAND GEOSYNCHRONOUS SYNTHETIC APERTURE RADAR MISSION ANALYSIS WITH MEDIUM TRANSMITTED POWER AND MEDIUM-SIZED ANTENNA Josep Ruiz Rodon, Antoni Broquetas,

A Multi-Channel Partial-Update Algorithm for

Outline Sparse Reconstruction RIP Condition

Introduction to SAR Imaging

Presentation transcript:

DISPLACED PHASE CENTER ANTENNA SAR IMAGING BASED ON COMPRESSED SENSING Yueguan Lin 1,2,3, Bingchen Zhang 1,2, Wen Hong 1,2 and Yirong Wu 1,2 1 National Key Laboratory of Science and Technology on Microwave Imaging, P. R. China 2 Institute of Electronics, Chinese Academy of Sciences (IECAS), Beijing, P. R. China 3 Graduate University of Chinese Academy of Sciences (GUCAS), Beijing, P. R. China Institute of Electronics, Chinese Academy of Sciences National Key Laboratory of Microwave Imaging Technology

Outlines Introduction DPCA SAR imaging based on Compressed Sensing Ground-based DPCA SAR experiment Conclusion and discussion Acknowledgement

Introduction High azimuth resolution and wide unambiguous swath coverage are contradictive in SAR system design. DPCA SAR has the potential to achieve HRWS imaging. While there is a rigid restriction posed on its selection of PRF: SAR platform moves just one half of its total antenna length between subsequent radar pulses. When this condition is not satisfied, there will be nonuniform sampling in azimuth and rising azimuth ambiguities will appear under traditional imaging algorithms based on matched filter

Introduction Krieger proposed A Doppler spectrum reconstruction algorithm *. This method can recover the unambiguous signal and suppress ambiguous energy. It is computation costly as inversions of matrix are involved and the reconstruction of spectrum should be carried out for every azimuth signal. * Krieger, G., Gebert, N., and Moreira, A.: ‘Unambiguous SAR signal reconstruction from nonuniform displaced phase center sampling’. IEEE Geoscience and Remote Sensing Letters, 2004, 1(4):

DPCA SAR imaging based on Compressed Sensing Compressed Sensing X is sparse representable if there exists a sparsity basis that provides a K sparse representation of it. When Φ satisfies Restricted Isometry Property. The number of measurements needed to reconstruct the signal is not restrained by the Nyquist sampling rate, but by the complexity of the signal. We only need M measurements, where where N is the number of measurements needed by the Nyquist Theorem

DPCA SAR imaging based on Compressed Sensing According to systems the DPCA SAR model can be constructed precisely where ， y is the observations x is observed scene Φ is observation matrix n is observation noise.

DPCA SAR imaging based on Compressed Sensing The backscattering field of target is usually contributed by a few strong scattering centers, so CS is suitable in SAR imaging. As the observation is constructed precisely according to SAR system parameters, the ambiguity causes by nonuniform effective azimuth phase centers doesn’t exist. The observed scene can be reconstructed through solving an optimization problem

Ground-based DPCA SAR experiment ParametersValues Carrier frequency17 GHz Based band width1 GHz Stepped frequencies2.5 MHz Span in azimuth[-1, 1] m Azimuth sampling interval0.024 m Length of subaperture0.032 m Ground-based DPCA SAR system with one aperture transmitting stepped frequency and three apertures receiving echoes. System parameters DPCA SAR system

Ground-based DPCA SAR experiment Antennas Azimuth effective phase centers. Effective azimuth phase centers of this DPCA SAR system are nonuniformly distributed.

Ground-based DPCA SAR experiment Observed trihedral corner reflector. RD imaging without preprocessing Result using traditional Range-Doppler algorithm without preprocessing has -17dB ambiguities.

Ground-based DPCA SAR experiment RD imaging with spectrum reconstruction Proposed CS imaging Result using RD algorithm after spectrum reconstruction has -25dB ambiguities; result using proposed imaging algorithm with ambiguities being suppressed under -30dB.

Conclusion and discussion DPCA SAR imaging algorithm based on CS can suppress the ambiguities caused by nonuniform sampling in azimuth and retrieve the target scene with high quality. The experimental results with ground-based DPCA SAR system validate its advantage.  We will evaluate this method’s performance with real space borne and airborne raw data in next step.  The effect of observation noise will be researched.

Acknowledgement This work was supported by the State Key Development Program for Basic Research of China (Grant No. 2010CB731905).

Thank you for your attention!