Method for Anisotropic Crystal-Orientation Fabrics Detection Using Radio-Wave Depolarization in Radar Sounding of Mars Polar Layered Deposits

Chen Wang, Zehua Dong, Xiaojuan Zhang*, Xiaojun Liu, Guangyou Fang

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

2 Citations (Scopus)

Abstract

The polar layered deposits (PLDs) provide a wealth of information about the past climate evolution of Mars. Surface mass fluxes and ice flow mainly governed topography and layering of the PLD. China's Mars probe including an orbiter and a landing rover will be launched by 2020. A new type satellite-borne Mars penetrating radar instrument has been selected to be a part of the payloads on the orbiter. Its main scientific objectives are to map the distribution of water, water-ice and to detect the soil characteristics at global scale on the Martian crust. Compared with Mars Advanced Radar for Subsurface and Ionospheric Sounding and Shallow Radar, the biggest difference is that the antenna system of this Mars penetrating radar consists of two dipole antennas mutually perpendicular. This special configuration enables the investigation of the ice flow of PLD by detecting and analyzing the features of anisotropic crystal-orientation fabric (COF). Thus, relying on the fact that the radio waves are depolarized while passing through an anisotropic COF layer, in this paper, a method for anisotropic COF detection based on this radar system is proposed. The radar echo formulation of anisotropic COF is derived and the ratio of the signals measured by the two perpendicular antennas is used to analyze the anisotropy of COF. We demonstrate that the ratio is an ideal criterion for the detection and analysis of COF, since it contains all parameters about the anisotropy feature of COF and it is independent of the attenuation in the propagation path and the reflection coefficient. In order to verify the validity of the derived analytical expression of the ratio for the detection of COF, finite-different time-domain simulations are carried out based on a simple model of the subsurface of PLD which contains an anisotropic COF layer. The advantages of this method, the potential application scenarios, and the effects of the Martian environment are also discussed.

Original languageEnglish
Article number8355720
Pages (from-to)5198-5206
Number of pages9
JournalIEEE Transactions on Geoscience and Remote Sensing
Volume56
Issue number9
DOIs
Publication statusPublished - Sept 2018
Externally publishedYes

Keywords

  • Anisotropic crystal-orientation fabric (COF)
  • Mars penetrating radar
  • Mars subsurface detection
  • ice flow
  • polar layered deposits (PLDs)
  • remote sensing

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