Use of Faraday-rotation data from beacon satellites to determine ionospheric corrections for interplanetary spacecraft navigation
Abstract
Faraday-rotation data from the linearly polarized 137-MHz beacons of the ATS-1, SIRIO, and Kiku-2 geosynchronous satellites are used to determine the ionospheric corrections to the range and Doppler data for interplanetary spacecraft navigation. The JPL operates the Deep Space Network of tracking stations for NASA; these stations monitor Faraday rotation with dual orthogonal, linearly polarized antennas, Teledyne polarization tracking receivers, analog-to-digital converter/scanners, and other support equipment. Computer software examines the Faraday data, resolves the pi ambiguities, constructs a continuous Faraday-rotation profile and converts the profile to columnar zenith total electron content at the ionospheric reference point; a second program computes the line-of-sight ionospheric correction for each pass of the spacecraft over each tracking complex. Line-of-sight ionospheric electron content using mapped Faraday-rotation data is compared with that using dispersive Doppler data from the Voyager spacecraft; a difference of about 0.4 meters, or 5 x 10 to the 16th electrons/sq m is obtained. The technique of determining the electron content of interplanetary plasma by subtraction of the ionospheric contribution is demonstrated on the plasma torus surrounding the orbit of Io.
- Publication:
-
Scientific and Engineering Uses of Satellite Radio Beacons
- Pub Date:
- 1981
- Bibcode:
- 1981seus.proc..345R
- Keywords:
-
- Beacon Satellites;
- Deep Space Network;
- Electron Density (Concentration);
- Faraday Effect;
- Interplanetary Navigation;
- Space Plasmas;
- Computer Techniques;
- Data Acquisition;
- Doppler Navigation;
- Ionospherics;
- Synchronous Satellites;
- Voyager Project;
- Space Communications, Spacecraft Communications, Command and Tracking