Development of an LSI maximum-likelihood convolutional decoder for advanced forward error correction capability on the NASA 30/20 GHz program
Abstract
The particular coding option identified as providing the best level of coding gain performance in an LSI-efficient implementation was the optimal constraint length five, rate one-half convolutional code. To determine the specific set of design parameters which optimally matches this decoder to the LSI constraints, a breadboard MCD (maximum-likelihood convolutional decoder) was fabricated and used to generate detailed performance trade-off data. The extensive performance testing data gathered during this design tradeoff study are summarized, and the functional and physical MCD chip characteristics are presented.
- Publication:
-
9th Communications Satellite Systems Conference
- Pub Date:
- 1982
- Bibcode:
- 1982coss.conf..142C
- Keywords:
-
- Data Transmission;
- Decoders;
- Error Correcting Codes;
- Error Correcting Devices;
- Large Scale Integration;
- Maximum Likelihood Estimates;
- Design Analysis;
- Microwave Transmission;
- Nasa Programs;
- Redundancy Encoding;
- Signal Processing;
- Superhigh Frequencies;
- Transmission Efficiency;
- Communications and Radar