A hardware spinal decoder

Author(s)

Iannucci, Peter A.; Fleming, Kermin Elliott; Perry, Jonathan; Balakrishnan, Hari; Shah, Devavrat

Abstract

Spinal codes are a recently proposed capacity-achieving rateless code. While hardware encoding of spinal codes is straightforward, the design of an efficient, high-speed hardware decoder poses significant challenges. We present the first such decoder. By relaxing data dependencies inherent in the classic M-algorithm decoder, we obtain area and throughput competitive with 3GPP turbo codes as well as greatly reduced latency and complexity. The enabling architectural feature is a novel alpha-beta incremental approximate selection algorithm. We also present a method for obtaining hints which anticipate successful or failed decoding, permitting early termination and/or feedback-driven adaptation of the decoding parameters. We have validated our implementation in FPGA with on-air testing. Provisional hardware synthesis suggests that a near-capacity implementation of spinal codes can achieve a throughput of 12.5 Mbps in a 65 nm technology while using substantially less area than competitive 3GPP turbo code implementations.

Date issued

2012-10

URI

http://hdl.handle.net/1721.1/85951

Department

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science

Journal

Proceedings of the eighth ACM/IEEE symposium on Architectures for networking and communications systems (ANCS '12)

Publisher

Association for Computing Machinery (ACM)

Citation

Peter A. Iannucci, Kermin Elliott Fleming, Jonathan Perry, Hari Balakrishnan, and Devavrat Shah. 2012. A hardware spinal decoder. In Proceedings of the eighth ACM/IEEE symposium on Architectures for networking and communications systems (ANCS '12). ACM, New York, NY, USA, 151-162.

Version: Author's final manuscript

ISBN

9781450316859