Title :
Parallel decoding for channels with jamming
Author :
Hassan, Amer A. ; Stark, Wayne E.
Author_Institution :
GE Corp., Schenectady, NY, USA
Abstract :
The authors describe optimum decoding algorithms that can be useful for channels with various forms of interference. These algorithms consider constrained receiver complexity in the following sense. For a fixed number of decoders or demodulators, or for a fixed tolerable time delay for multiple decoding attempts, what is the best decoding algorithm? Optimality is defined as the maximum least cost incurred by a jammer to cause a decoding error (or failure). The design of the decoders or demodulators is determined by a set of thresholds, each of which determines an erasure region. It is demonstrated that the formulation considered here is solvable for many channels including the simple M-ary input-output channel with the Hamming distance as the cost function, the additive channel where the cost function corresponds to Euclidean distance, and a noncoherent channel with ratio-threshold-like decision rules and difference metric decision rules
Keywords :
decoding; interference (signal); jamming; telecommunication channels; Euclidean distance; Hamming distance; M-ary input-output channel; additive channel; constrained receiver complexity; cost function; decoders; decoding error; demodulators; difference metric decision rules; erasure region; failure; interference; jamming; maximum least; noncoherent channel; optimum decoding algorithms; parallel decoding; ratio-threshold-like decision rules; time delay; Additive white noise; Concatenated codes; Cost function; Decoding; Demodulation; Error correction; Euclidean distance; Hamming distance; Interference; Jamming;
Conference_Titel :
Military Communications Conference, 1992. MILCOM '92, Conference Record. Communications - Fusing Command, Control and Intelligence., IEEE
Conference_Location :
San Diego, CA
Print_ISBN :
0-7803-0585-X
DOI :
10.1109/MILCOM.1992.244009
