Title :
Error control techniques for data sequences defined in finite integer rings
Author_Institution :
Philips Consumer Commun., Piscataway, NJ, USA
Abstract :
We present results that can be used to design cyclic codes for data sequences defined in finite integer and complex integer rings. This follows from the previous work on generalization of the well-known Euler´s theorem in finite integer rings and their polynomial extensions. The idea is to describe BCH and Reed-Solomon codes in these rings along with a decoding algorithm. The decoding algorithm in the ring employs the decoder in the finite field in an iterative manner. All the algebraic properties of the resulting codes follow from the underlying finite fields
Keywords :
BCH codes; Reed-Solomon codes; binary sequences; cyclic codes; error correction codes; iterative decoding; polynomials; BCH codes; Chinese remainder theorem; Euler´s theorem; Reed-Solomon codes; algebraic properties; complex integer rings; cyclic codes design; data sequences; decoding algorithm; error control coding; error control techniques; finite integer rings; iterative decoder; polynomial extensions; Algebra; Cathode ray tubes; Error correction; Error correction codes; Fault tolerant systems; Galois fields; Iterative algorithms; Iterative decoding; Polynomials; Reed-Solomon codes;
Conference_Titel :
Global Telecommunications Conference, 1998. GLOBECOM 1998. The Bridge to Global Integration. IEEE
Conference_Location :
Sydney,NSW
Print_ISBN :
0-7803-4984-9
DOI :
10.1109/GLOCOM.1998.776594
