Title :
Improved VLSI designs for multiplication and inversion in GF(2M) over normal bases
Author :
Gao, Lijun ; Sobelman, Gerald E.
Author_Institution :
Dept. of Electr. & Comput. Eng., Minnesota Univ., Duluth, MN, USA
Abstract :
Finite field arithmetic circuits are a core part for implementing some cryptographic systems and Reed-Solomon codes. In this paper, improved VLSI designs for computing multiplication and inverse in GF(2 m) over normal bases are presented. The improvements over the previous publications for the Massey-Omura multiplier include both circuit and architecture (or logic) levels. At circuit level, the improved design reduces the area and power consumption, and is faster than the previous design. At architecture level, the new design reduces logic complexity and is more regular, which, in turn, allows static CMOS design and reduces power dissipation. The latency of the inversion method is reduced with parallelism exploration at no cost in hardware. Therefore, the work presented in this paper can provide better VLSI designs in terms of performance and power consumption
Keywords :
CMOS logic circuits; Reed-Solomon codes; VLSI; cryptography; digital arithmetic; multiplying circuits; GF(2M); Massey-Omura multiplier; Reed-Solomon codes; VLSI designs; area; circuit level; cryptographic systems; finite field arithmetic circuits; inversion; inversion method; logic complexity; multiplication; normal bases; parallelism exploration; power consumption; power dissipation; static CMOS design; Arithmetic; CMOS logic circuits; Computer architecture; Cryptography; Energy consumption; Galois fields; Logic circuits; Logic design; Reed-Solomon codes; Very large scale integration;
Conference_Titel :
ASIC/SOC Conference, 2000. Proceedings. 13th Annual IEEE International
Conference_Location :
Arlington, VA
Print_ISBN :
0-7803-6598-4
DOI :
10.1109/ASIC.2000.880683
