F. Naessens, B. Bougard, Siebert Bressinck, L. Hollevoet, P. Raghavan, L. Perre, F. Catthoor
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A unified instruction set programmable architecture for multi-standard advanced forward error correction
The continuously increasing number of communication standards to be supported in nomadic devices combined with the fast ramping design cost in deep submicron technologies claim for highly reusable and flexible programmable solutions. Software defined radio (SDR) aims at providing such solutions in radio baseband architectures. Great advances were recently booked in handset-targeted SDR, covering most of the baseband processing with satisfactory performance and energy efficiency. However, as it typically depicts a magnitude higher computation load, forward error correction (FEC) has been excluded from the scope of high throughput SDR solutions and let to dedicated hardware accelerators. The currently growing number of advanced FEC options claims however for flexibility there too. This paper presents the first application-specific instruction programmable architecture addressing in a unified way the emerging turbo- and LPDC coding requirements of 3GPP-LTE, IEEE802.11n, IEEE802.16(e) and DVB-S2/T2. The proposal shows a throughput from 0.07 to 1.25 Mbps/MHz with efficiencies round 0.32 nJ/bit/iter in turbo mode and round 0.085 nJ/bit/iter in LDPC mode. The area is lower than the cumulated area of dedicated turbo and LDPC solution.
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