On-board landmark navigation and attitude reference parallel processor system
Abstract
An approach to autonomous navigation and attitude reference for earth observing spacecraft is described along with the landmark identification technique based on a sequential similarity detection algorithm (SSDA). Laboratory experiments undertaken to determine if better than one pixel accuracy in registration can be achieved consistent with onboard processor timing and capacity constraints are included. The SSDA is implemented using a multi-microprocessor system including synchronization logic and chip library. The data is processed in parallel stages, effectively reducing the time to match the small known image within a larger image as seen by the onboard image system. Shared memory is incorporated in the system to help communicate intermediate results among microprocessors. The functions include finding mean values and summation of absolute differences over the image search area. The hardware is a low power, compact unit suitable to onboard application with the flexibility to provide for different parameters depending upon the environment.
- Publication:
-
Flight Mechanics/Estimation Theory Symposium
- Pub Date:
- May 1978
- Bibcode:
- 1978fmet.symp..153G
- Keywords:
-
- Airborne/Spaceborne Computers;
- Artificial Satellites;
- Parallel Processing (Computers);
- Satellite Attitude Control;
- Satellite Navigation Systems;
- Algorithms;
- Autonomous Navigation;
- Computer Techniques;
- Image Resolution;
- Landmarks;
- Microprocessors;
- Orbital Mechanics;
- Satellite Orbits;
- Space Navigation;
- Astrodynamics