This paper presents a novel high-speed BCH decoder that corrects double-adjacent and single-bit errors in parallel and serially corrects multiple-bit errors other than double-adjacent errors. Its operation is based on extending an existing parallel BCH decoder that can only correct single-bit errors and serially corrects double-adjacent errors at low speed. The proposed de- coder is constructed by a novel design and is suitable for nanoscale memory systems, in which multiple-bit errors occur at a probability comparable to single-bit errors and double-adjacent errors occur at a higher probability (nearly two orders of magnitude) than other multiple-bit errors. Extensive simulation results are reported. Compared with the existing scheme, the area and de- lay time of the proposed decoder are on average 11% and 6% higher, but its power consumption is reduced by 9% on average. This paper also shows that the area, delay, and power overheads incurred by the proposed scheme are significantly lower than traditional fully parallelized BCH decoders capable of correcting any double-bit errors in parallel.
A single-bit and double-adjacent error correcting parallel decoder for multiple-bit error correcting BCH codes / Namba, K; Pontarelli, S; Ottavi, M; Lombardi, F. - In: IEEE TRANSACTIONS ON DEVICE AND MATERIALS RELIABILITY. - ISSN 1530-4388. - 14:2(2014), pp. 664-671. [10.1109/TDMR.2014.2309935]
A single-bit and double-adjacent error correcting parallel decoder for multiple-bit error correcting BCH codes
Pontarelli S;
2014
Abstract
This paper presents a novel high-speed BCH decoder that corrects double-adjacent and single-bit errors in parallel and serially corrects multiple-bit errors other than double-adjacent errors. Its operation is based on extending an existing parallel BCH decoder that can only correct single-bit errors and serially corrects double-adjacent errors at low speed. The proposed de- coder is constructed by a novel design and is suitable for nanoscale memory systems, in which multiple-bit errors occur at a probability comparable to single-bit errors and double-adjacent errors occur at a higher probability (nearly two orders of magnitude) than other multiple-bit errors. Extensive simulation results are reported. Compared with the existing scheme, the area and de- lay time of the proposed decoder are on average 11% and 6% higher, but its power consumption is reduced by 9% on average. This paper also shows that the area, delay, and power overheads incurred by the proposed scheme are significantly lower than traditional fully parallelized BCH decoders capable of correcting any double-bit errors in parallel.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.