Title :
Circuit techniques for CMOS low-power high-performance multipliers
Author :
Abu-Khater, Issam S. ; Bellaouar, Abdellatif ; Elmasry, M.I.
fDate :
10/1/1996 12:00:00 AM
Abstract :
In this paper we present circuit techniques for CMOS low-power high-performance multiplier design. Novel full adder circuits were simulated and fabricated using 0.8-μm CMOS (in BiCMOS) technology. The complementary pass-transistor logic-transmission gate (CPL-TG) full adder implementation provided an energy savings of 50% compared to the conventional CMOS full adder. CPL implementation of the Booth encoder provided 30% power savings at 15% speed improvement compared to the static CMOS implementation. Although the circuits were optimized for (16×16)-b multiplier using the Booth algorithm, a (6×6)-b implementation was used as a test vehicle in order to reduce simulation time. For the (6×6)-b case, implementation based on CPL-TG resulted in 18% power savings and 30% speed improvement over conventional CMOS
Keywords :
CMOS logic circuits; digital arithmetic; encoding; integrated circuit design; logic design; multiplying circuits; 0.8 micron; Booth algorithm; Booth encoder; CMOS low-power multipliers; circuit techniques; complementary pass-transistor logic-transmission gate; full adder circuits; high-performance multipliers; Adders; BiCMOS integrated circuits; CMOS logic circuits; CMOS technology; Circuit simulation; Circuit testing; Digital signal processing; Partitioning algorithms; Signal processing algorithms; Very large scale integration;
Journal_Title :
Solid-State Circuits, IEEE Journal of
