Reconstruction of Synthetic Aperture Radar Raw Data under Analog-To-Digital Converter Saturation Distortion for Large Dynamic Range Scenes

Digital storage and transmission are common processes in modern synthetic aperture radar systems; thus, analog-to-digital converters are indispensable. Such processes can lead to two types of error: quantization (or granular) error and saturation (or clipping) error, which cause sampling noise, and radiometric and harmonic distortions in final images. Traditionally, reasonable choices of the gain and the number of quantization bits by the analog-to-digital converter based on the echo distribution can effectively reduce these errors. However, establishing the gain control repository of a synthetic aperture radar mission is a long process. In addition, if the dynamic range of the backscattering coefficient is extremely large or if unexpected strong targets appear in a scene, then harmonics occur in the echo, which turns the variable gain amplifier into chaos based on statistic and, inevitably, results in saturation in the raw data. Once raw data saturation occurs, the SAR system can conventionally adjust only the analog-to-digital converter in the next observation, thus reducing timeliness. Power loss compensation based on a statistical model and saturation (clipping) factor on a large-scale could compensate for the energy loss in images; however, detail interference, such as harmonic distortion, cannot be effectively suppressed, which will lead to false targets in the focused data. To address this particular problem, a novel anti-saturation method for large dynamic range scenes is proposed in this paper. The log-normal distribution is used in this article to describe dynamic range scenes with strong isolated targets, which mainly cause receiver saturation. Using the statistical distribution of complex scenes as a priori information, a maximum a posteriori estimation algorithm is proposed to simultaneously compensate for the saturated values in the raw data and retain the non-saturated values. Thus, the details of the weak background are well preserved, and the isolated strong targets with sparsity are reconstructed perfectly. With Monte Carlo simulation, the proposed method can improve the radiometric accuracy by 5 to 10 dB and effectively suppress the energy of false targets. Based on TerraSAR-X, ALOS-2, and Radarsat-1 synthetic aperture radar data, the effectiveness and robustness of the proposed method are also verified by simulations.

[1]  Joel Max,et al.  Quantizing for minimum distortion , 1960, IRE Trans. Inf. Theory.

[2]  Ron Kwok,et al.  Block adaptive quantization of Magellan SAR data , 1989 .

[3]  Joachim H. G. Ender,et al.  On compressive sensing applied to radar , 2010, Signal Process..

[4]  Yongqiang Zhang,et al.  Effects of receiver saturation on image formation , 2011, 2011 IEEE International Geoscience and Remote Sensing Symposium.

[5]  John C. Curlander,et al.  Synthetic Aperture Radar: Systems and Signal Processing , 1991 .

[6]  Robert Blumgold,et al.  Quantization and Saturation Noise Due to Analog-to-Digital Conversion of Radar Returns from Targets with Log-Normal Radar Cross-Section Distributions , 1977, IEEE Transactions on Aerospace and Electronic Systems.

[7]  Yunhua Zhang,et al.  A MAP Approach for 1-Bit Compressive Sensing in Synthetic Aperture Radar Imaging , 2015, IEEE Geoscience and Remote Sensing Letters.

[8]  Masanobu Shimada Radiometric correction of saturated SAR data , 1999, IEEE Trans. Geosci. Remote. Sens..

[9]  Ian G. Cumming,et al.  The effect of pulse phase errors on the chirp scaling SAR processing algorithm , 1996, IEEE Trans. Geosci. Remote. Sens..

[10]  Ian G. Cumming,et al.  Digital Processing of Synthetic Aperture Radar Data: Algorithms and Implementation , 2005 .

[11]  Giorgio Franceschetti,et al.  Phase quantized SAR signal processing: theory and experiments , 1999 .

[12]  Gerhard Krieger,et al.  Quantization Effects in TanDEM-X Data , 2015, IEEE Transactions on Geoscience and Remote Sensing.

[13]  G. R. Valenzuela,et al.  Point-Scatterer Formulation of Terrain Clutter Statistics , 1972 .

[14]  C. E. Livingstone,et al.  Adaptive Compensation of RADARSAT SAR Analoque-to-Digital Converter Saturation Power Loss , 1997 .

[15]  G. Zeoli,et al.  Quantization and Saturation Noise Due to Analog-to-Digital Conversion , 1971, IEEE Transactions on Aerospace and Electronic Systems.

[16]  Elke Malz,et al.  Sentinel-1 FDBAQ performance validation using TerraSAR-X data , 2012, 2012 IEEE International Geoscience and Remote Sensing Symposium.

[17]  D. Cheng Degradation effects of arbitrary phase errors on high-resolution radar performance , 1964 .

[18]  Patrick Denny,et al.  Pre-processing compensation for saturation power loss in SAR data , 2002, IEEE International Geoscience and Remote Sensing Symposium.

[19]  Benjamin Bräutigam,et al.  Radar Backscatter Mapping Using TerraSAR-X , 2011, IEEE Transactions on Geoscience and Remote Sensing.

[20]  Glenn R. Heidbreder,et al.  Detection Probabilities for Log-Normally Distributed Signals , 1967, IEEE Transactions on Aerospace and Electronic Systems.

[21]  Robert Metzig,et al.  TerraSAR-X System Performance Characterization and Verification , 2010, IEEE Transactions on Geoscience and Remote Sensing.

[22]  Yan Wang,et al.  Effect of AD Converter saturation on SAR system performance , 2013, Conference Proceedings of 2013 Asia-Pacific Conference on Synthetic Aperture Radar (APSAR).

[23]  Richard G. Baraniuk,et al.  1-Bit compressive sensing , 2008, 2008 42nd Annual Conference on Information Sciences and Systems.

[24]  Ze Yu,et al.  The Recovery Algorithm of Saturated Sar Raw Data Based on Compressed Sensing , 2018, IGARSS 2018 - 2018 IEEE International Geoscience and Remote Sensing Symposium.

[25]  V. Pascazio,et al.  Processing of signum coded SAR signal: theory and experiments , 1991 .

[26]  Alberto Moreira,et al.  A comparison of several algorithms for SAR raw data compression , 1995, IEEE Trans. Geosci. Remote. Sens..