论文信息 - High speed and high throughput 8×8 bit multiplier using a Shannon-based adder cell

High speed and high throughput 8×8 bit multiplier using a Shannon-based adder cell

The adder circuit is used as a main component in the multiplier circuits. The Baugh-Wooley, Braun and CSA multipliers are designed by using our proposed adder cell. The proposed adder circuit is designed by using Shannon theorem. The multiplier circuits are schematised by using DSCH2 VLSI CAD tool and their layouts are generated by using Microwind 3 VLSI CAD tool. The proposed adder based multiplier circuits are simulated and results are compared with MCIT and CPL based adder cell in terms of power, area, delay, EPI, Throughput, and Latency. The proposed adder based multiplier circuits are simulated by using 90nm feature size and corresponding supply voltage 1V. The Shannon full adder circuit based multiplier circuits gives better performance than other published results in terms of power dissipation, propagation delay, throughput and latency due to less number of transistor used in Shannon adder circuit. Since the maximum drain current is also not increasing significantly with temperature in our multiplier circuits, therefore, power dissipation of the circuit is less.

Ajay Kumar Singh | C. Senthilpari | K. Diwakar

[1] Kyoung-Su Park,et al. Design and implementation of a high-speed matrix multiplier based on word-width decomposition , 2006, IEEE Trans. Very Large Scale Integr. Syst..

[2] W. C. Miller,et al. An Efficient Tree Architecture for Modulo 2 n + 1 Multiplication Journal of VLSI Signal Processing , 1996 .

[3] Ajay Kumar Singh,et al. Design of a low-power, high performance, 8×8 bit multiplier using a Shannon-based adder cell , 2008, Microelectron. J..

[4] Zine-Eddine Abid,et al. Low power multipliers based on new hybrid full adders , 2008, Microelectron. J..

[5] Yutai Ma. A Slimplified Architecture for Modulo (2n + 1) Multiplication , 1998, IEEE Trans. Computers.

[6] Wolfgang Fichtner,et al. Low-power logic styles: CMOS versus pass-transistor logic , 1997, IEEE J. Solid State Circuits.

[7] Donald A. Neamen,et al. Microelectronics Circuit Analysis and Design , 2006 .

[8] L. Sousa,et al. A universal architecture for designing efficient modulo 2/sup n/+1 multipliers , 2005, IEEE Transactions on Circuits and Systems I: Regular Papers.

[9] Vojin G. Oklobdzija,et al. General method in synthesis of pass-transistor circuits , 2000 .