Backscattering Analysis for Snow Remote Sensing Model With Higher Order of Surface-Volume Scattering

Syahali, Syabeela; Ewe, Hong Tat

doi:10.2528/pierm15122601

Cited by 5 publications

(5 citation statements)

References 15 publications

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“…In future, this study can be extended to a layer or to layers of scatterers, as in real vegetation media, with the ability to model more realistic shapes of scatterers. By combining the RHESA with radiative transfer theory solution and DMPACT, the total backscattering return from layers of dense media can be modelled as in previous studies [2,5,7,8,11], but with more accurate results for vegetation media.…”

Section: Discussionmentioning

confidence: 99%

“…Theoretical models in microwave remote sensing research have been developed using analytical methods that employ approximation models [1][2][3][4][5][6][7][8][9][10][11][12], especially for vegetation media [9][10][11][12]. Analytical method models can provide some physical insight into media, and allow the study of scattering behaviour for variations in parameters; however, their accuracy is limited, as this is carried out by approximating the scatterers into limited shapes such as spheres, cylinders, needles, ellipsoids, and elliptic discs.…”

Section: Introductionmentioning

confidence: 99%

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Backscattering Analysis Utilizing Relaxed Hierarchical Equivalent Source Algorithm (RHESA) for Scatterers in Vegetation Medium

et al. 2022

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The backscattering cross section of cylindrical and elliptical disk-shaped scatterers was investigated in this study, utilising a new numerical solution method called the relaxed hierarchical equivalent source algorithm (RHESA). The results were compared with the backscattering cross section of similar cases, using analytical method validation from literature. The objective of this research was to look into the possibility of replacing analytical methods with the RHESA in volume scattering calculations, and integrating it into modelling the backscattering of layers of dense media for microwave remote sensing in vegetation; as RHESA provides the freedom to model any shape of scatterer, as opposed to the limited shapes available of scatterers in analytical method models. The results demonstrated a good match, indicating that the RHESA may be a good fit for modelling more complicated media, such as vegetation, in future studies.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Backscattering Analysis Utilizing Relaxed Hierarchical Equivalent Source Algorithm (RHESA) for Scatterers in Vegetation Medium

et al. 2022

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“…where k is the wave number, k x = k sin θ cos φ , k y = k sin θ sin φ , k z = k cos θ , k sx , k sy and k sz have similar definitions by replacing θ and φ with θ s and φ s , pp represents VV or HH polarization, S(θ , θ s ) is the shadowing function defined by Sancer [31] (Appendix A), σ is the RMS height of the surface, W n is the Fourier transform of the n-th power of the surface correlation coefficient (Appendix B), and the expression for I n pp is given in Appendix C. Top surface scattering can be expressed as…”

Section: Sea Ice Electromagnetic Scattering Modelmentioning

confidence: 99%

“…The shadowing function proposed by Sancer [31] is a function of incident angle, θ , scattering angle, θ s , and surface root mean square slope, σ s , which can be written in the following form: where erfc is the error-function complement related to the error function erf by…”

Section: Appendix A: Shadowing Functionmentioning

confidence: 99%

“…They developed an algorithm for retrieving the ice thickness, which is based on the backscattering ratio and IEM. In Syahali and Ewe's work, [31] multiplesurface scattering, based on IEM that calculates surface scattering and additional second-order surface-volume scattering, was added into the model (based on prior studies) for improvement in the backscattering calculation.…”

Section: Introductionmentioning

confidence: 99%

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Polarization ratio characteristics of electromagnetic scattering from sea ice in polar areas

Zhao¹,

Xie²,

Meng³

et al. 2018

Chinese Phys. B

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In the global climate system, the polar regions are sensitive indicators of climate change, in which sea ice plays an important role. Satellite remote sensing is a significant tool for monitoring sea ice. The use of synthetic aperture radar (SAR) images to distinguish sea ice from sea water is one of the current research hotspots in this topic. To distinguish sea ice from the open sea, the polarization ratio characteristics of sea ice and sea water are studied for L-band and C-band radars, based on an electromagnetic scattering model of sea ice derived from the integral equation method (IEM) and the radiative transfer (RT) model. Numerical experiments are carried out based on the model and the results are given as follows. For L-band, the polarization ratio for sea water depends only on the incident angle, while the polarization ratio for sea ice is related to the incident angle and the ice thickness. For C-band, the sea water polarization ratio is influenced by the incident angle and the root mean square (RMS) height of the sea surface. For C-band, for small to medium incident angles, the polarization ratio for bare sea ice is mainly determined by the incident angle and ice thickness. When the incident angle increases, the RMS height will also affect the polarization ratio for bare sea ice. If snow covers the sea ice, then the polarization ratio for sea ice decreases and is affected by the RMS height of snow surface, snow thickness, volume fraction and the radius of scatterers. The results show that the sea ice and the open sea can be distinguished by using either L-band or C-band radar according to their polarization ratio difference. However, the ability of L-band to make this differentiation is higher than that of C-band.

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Multifrequency Microwave Backscatter From a Highly Saline Snow Cover on Smooth First-Year Sea Ice: First-Order Theoretical Modeling

Nandan

Geldsetzer

Yackel

et al. 2017

IEEE Trans. Geosci. Remote Sensing

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Backscattering Analysis for Snow Remote Sensing Model With Higher Order of Surface-Volume Scattering

Cited by 5 publications

References 15 publications

Backscattering Analysis Utilizing Relaxed Hierarchical Equivalent Source Algorithm (RHESA) for Scatterers in Vegetation Medium

Backscattering Analysis Utilizing Relaxed Hierarchical Equivalent Source Algorithm (RHESA) for Scatterers in Vegetation Medium

Polarization ratio characteristics of electromagnetic scattering from sea ice in polar areas

Multifrequency Microwave Backscatter From a Highly Saline Snow Cover on Smooth First-Year Sea Ice: First-Order Theoretical Modeling

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