In this paper a review of different techniques used to implement highly optimized DSP systems is presented. The case of study is the implementation of parallel FIR filters aimed to applications characterized by high speed and high selectivity in frequency where at the same time low power dissipation is mandatory. After a review of the possible "standard" optimization techniques, the paper addresses aggressive methodologies where power and area savings are obtained by introducing the concept of "Degrading Precision Arithmetic" (DPA). Three different approaches are discussed: DPA-I, based on selective bit freezing, DPA-II, based on VDD voltage scaling, and DPA-III, based on power gating. Some theoretical/simulative analysis of the introduced arithmetic errors and some implementation results are shown. A discussion on the suitability of these methodologies on standard cell technologies and FPGAs is also addressed. In our experience, these techniques are well known in the scientific community, but they are not extensively known in the design community, and, consequently, they are scarcely utilized. © 2011 IEEE.
Albicocco, P., Cardarilli, G.c., Nannarelli, A., Petricca, M., Re, M. (2011). Degrading precision arithmetics for low-power FIR implementation. In Midwest Symposium on Circuits and Systems (pp.1-4). Piscataway - NJ : IEEE [10.1109/MWSCAS.2011.6026265].
Degrading precision arithmetics for low-power FIR implementation
CARDARILLI, GIAN CARLO;RE, MARCO
2011-01-01
Abstract
In this paper a review of different techniques used to implement highly optimized DSP systems is presented. The case of study is the implementation of parallel FIR filters aimed to applications characterized by high speed and high selectivity in frequency where at the same time low power dissipation is mandatory. After a review of the possible "standard" optimization techniques, the paper addresses aggressive methodologies where power and area savings are obtained by introducing the concept of "Degrading Precision Arithmetic" (DPA). Three different approaches are discussed: DPA-I, based on selective bit freezing, DPA-II, based on VDD voltage scaling, and DPA-III, based on power gating. Some theoretical/simulative analysis of the introduced arithmetic errors and some implementation results are shown. A discussion on the suitability of these methodologies on standard cell technologies and FPGAs is also addressed. In our experience, these techniques are well known in the scientific community, but they are not extensively known in the design community, and, consequently, they are scarcely utilized. © 2011 IEEE.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
