TEC retrieval from spaceborne SAR data and its applications

Wang, Cheng; Min, Zhang; Xu, Zhengwen; Hongwei, Zhao

doi:10.1002/2014ja020078

Cited by 12 publications

(8 citation statements)

References 35 publications

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“…The initial and true values of electron density are chosen from 100°E–120°E longitude, 10°N–30°N latitude, and 200 km–600 km height. In current spaceborne SAR CIT studies, the grid spacing is around 10–40 km in vertical and around 0.5° in latitude [ Li , ; Li and Li , ; Wang et al ., ]. Correspondingly, the space of ionosphere is divided into 8000 grids, with 0.5° interval in latitude, 1° interval in longitude, and 40 km interval in vertical.…”

Section: Numerical Simulationsmentioning

confidence: 99%

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Computerized ionospheric tomography based on geosynchronous SAR

Tian

Dong

et al. 2017

JGR Space Physics

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Computerized ionospheric tomography (CIT) based on spaceborne synthetic aperture radar (SAR) is an emerging technique to construct the three‐dimensional (3‐D) image of ionosphere. The current studies are all based on the Low Earth Orbit synthetic aperture radar (LEO SAR) which is limited by long repeat period and small coverage. In this paper, a novel ionospheric 3‐D CIT technique based on geosynchronous SAR (GEO SAR) is put forward. First, several influences of complex atmospheric environment on GEO SAR focusing are detailedly analyzed, including background ionosphere and multiple scattering effects (induced by turbulent ionosphere), tropospheric effects, and random noises. Then the corresponding GEO SAR signal model is constructed with consideration of the temporal‐variant background ionosphere within the GEO SAR long integration time (typically 100 s to 1000 s level). Concurrently, an accurate total electron content (TEC) retrieval method based on GEO SAR data is put forward through subband division in range and subaperture division in azimuth, obtaining variant TEC value with respect to the azimuth time. The processing steps of GEO SAR CIT are given and discussed. Owing to the short repeat period and large coverage area, GEO SAR CIT has potentials of covering the specific space continuously and completely and resultantly has excellent real‐time performance. Finally, the TEC retrieval and GEO SAR CIT construction are performed by employing a numerical study based on the meteorological data. The feasibility and correctness of the proposed methods are verified.

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Section: Numerical Simulationsmentioning

confidence: 99%

“…Wang et al . [] proposed a method to retrieve absolute TEC value by dividing subbands and taking into account the effects of multiple scattering. Meyer et al .…”

Section: Introductionmentioning

confidence: 99%

Computerized ionospheric tomography based on geosynchronous SAR

Tian

Dong

et al. 2017

JGR Space Physics

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“…As a high-resolution active microwave sensor, the spaceborne synthetic aperture radar (SAR) has been widely used in civil and military fields for decades, such as target detection and recognition, resource exploration, biomass classification and retrieval, and topographic surveying [e.g., Pettersson, 2004;Toan et al, 2011;Yang et al, 2015]. Recently, the use of low-frequency spaceborne SAR for measuring ionospheric information, i.e., the total electron content (TEC), has attracted increasing interest [e.g., Meyer et al, 2006;Rosen et al, 2010;Jehle et al, 2010;Meyer, 2011;Pi et al, 2011;Wang et al, 2014;Maeda et al, 2016]. Combining with the high spatial resolution of spaceborne SAR, this new field has the capability to obtain a kilometer-scale TEC distribution, which is difficult to be detected by conventionally used data source [Pi, 2015].…”

Section: Introductionmentioning

confidence: 99%

“…Given the different signal delay within the bandwidth, the range quadratic phase error (QPE) arises and further degrades the range resolution. TEC values can then be retrieved from the QPE by autofocus algorithm [ Jehle et al ., ; Wang et al ., ]. However, current low‐frequency spaceborne SAR systems, e.g., the Advanced Land Observing Satellite phased array L‐band synthetic aperture radar (PALSAR), have low sensitivity regarding TEC and require a strong point target with high signal‐to‐clutter ratio.…”

Section: Introductionmentioning

confidence: 99%

Improved TEC retrieval based on spaceborne PolSAR data

et al. 2017

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It is well known that for Earth observations, the spaceborne synthetic aperture radar (SAR) systems at L‐band can be seriously affected by the ionosphere. Fortunately, the destructive ionospheric information, total electron content (TEC), can be retrieved and removed by model inversion from SAR echoes and becomes a subject of interest for ionospheric research. Considering the system noise and channel phase imbalance, this paper focuses on accurate TEC retrieval from the Faraday rotation angle, which is embedded in Advanced Land Observing Satellite phased array L‐band synthetic aperture radar (PALSAR) full‐pol data. For the consideration of denoising, averaging filtering is widely used in existing studies to remove the system noise. In order to further reduce the noise effects, a fast total variation (FTV) denoising method is applied in this paper. By using the PALSAR full‐pol data sets, a series of simulation results show that the FTV denoising is effective for noise suppression and markedly reduce the standard deviation. For the error of channel phase imbalance, a new Faraday estimator based on the covariance matrix of circular basis is proposed. Compared with previous estimators, theoretical analysis and simulation results show that this new estimator can give the best performance for sensors that are dominated by channel phase imbalance errors. Thus, the proposed estimator can be a candidate method for TEC retrieval when phase imbalance is the domain error.

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“…During the last decade, ionospheric effects on spaceborne radar systems have drawn attention of Earth and space scientists [e.g., Ishimaru et al , ; Liu et al , ; Freeman , ; Chapin et al , ; Pi and Chan , ; Freeman et al , ; Meyer and Nicoll , ; Shimada et al , ; Rosen et al , , ; Pi et al , ; Rosen et al , ; Meyer , ; Kim et al , ; Carrano et al , ; Pi et al , ; Chen , ; Kim , ; Kim and Papathanassiou , ; Belcher and Cannon , ; Rogers and Quegan , ; Wang et al , ]. The motivation can be at least partially attributed to development and operation of L band and P band remote sensing radar systems for Earth observations.…”

mentioning

confidence: 99%

Ionospheric Effects on Spaceborne Synthetic Aperture Radar and a New Capability of Imaging the Ionosphere From Space

2015

Space Weather

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This article reviews research activities and results in a new field, where ionospheric effects on spaceborne synthetic aperture radar have been investigated and techniques of imaging the ionosphere using the same radar are also explored. The research was originally to minimize ionospheric‐induced distortions and contaminations in Earth remote sensing observations. As a product, the radar‐based high‐resolution ionospheric imaging from a low Earth orbit satellite can also benefit studies of space weather effects on the ionospheric density distribution in essentially all latitude regions, which would provide useful information to studies of coupling of the magnetosphere, ionosphere, and thermosphere.

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TEC retrieval from spaceborne SAR data and its applications

Cited by 12 publications

References 35 publications

Computerized ionospheric tomography based on geosynchronous SAR

Computerized ionospheric tomography based on geosynchronous SAR

Improved TEC retrieval based on spaceborne PolSAR data

Ionospheric Effects on Spaceborne Synthetic Aperture Radar and a New Capability of Imaging the Ionosphere From Space

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