Bistatic radar probing of planetary surfaces

Author

Simpson, Richard A. ; Tyler, G. Leonard ; Häusler, Bernd ; Pätzold, Martin ; Asmar, Sami

Author_Institution

Electr. Eng., Stanford Univ., Stanford, CA

fYear

2009

Firstpage

1

Lastpage

4

Abstract

Bistatic radar provides a simple, cost-effective way to obtain survey information about planetary surfaces on scales important to landers and rovers. The centimeter-scale waves interact most strongly with surface structure on similar and slightly larger scales yielding estimates of rms surface slopes zeta and material dielectric constant epsiv (which can be related to density). Recent experiments in the Mars north polar region show an unusually heterogeneous surface with some segments having zeta less than 0.2deg. The dielectric constants appear to vary only between 1.8 within the polar cap (snow) and 3-4 outside (sand). Uplink experiments (transmissions from ground to spacecraft) have been successfully conducted using Mars Odyssey; future possibilities include spacecraft-to-spacecraft experiments.

Keywords

Mars; planetary remote sensing; planetary surfaces; radar applications; Mars Odyssey; Mars north polar region; bistatic radar probing; centimeter-scale waves; material dielectric constant; planetary surface structure; rms surface slopes; spacecraft-to-spacecraft experiments; Bistatic radar; Dielectric constant; Dielectric materials; Doppler shift; Fresnel reflection; Geometry; Rough surfaces; Space vehicles; Surface roughness; Surface waves;

fLanguage

English

Publisher

ieee

Conference_Titel

Radar Conference, 2009 IEEE

Conference_Location

Pasadena, CA

ISSN

1097-5659

Print_ISBN

978-1-4244-2870-0

Electronic_ISBN

1097-5659

Type

conf

DOI

10.1109/RADAR.2009.4976965

Filename

4976965