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Low-Power High-Accuracy Fixed-Width Radix-8 Booth Multiplier Using Probabilistic Estimation Technique

Saroja S. Bhusare

JSS Academy of Technical Education, Bangalore, India

School of Electronics Engineering, VIT, Chennai, India

E-mail Address: saroja_sush@yahoo.co.in

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and

V. S. Kanchana Bhaaskaran

School of Electronics Engineering, VIT, Chennai, India

E-mail Address: vskanchana@gmail.com

Corresponding author.

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https://doi.org/10.1142/S0218126617500797Cited by:3 (Source: Crossref)

Abstract

In many Multimedia and DSP applications, the fixed-width multipliers are used to avoid infinite growth in the word size. Fixed-width multiplier produces an $n$ $n$ -bit product with two $n$ $n$ -bit inputs. This paper presents probabilistic estimation technique applied for the fixed-width radix-8 Booth multiplier for the generation of the compensation bias circuit. The probabilistic estimation circuit for the fixed-width radix-8 Booth multiplier is derived systematically from theoretical computation in preference to time-consuming exhaustive simulations. Results show that the radix-8 direct truncated multiplier reduces the maximum absolute error by 33%, the average error by 22% and the mean square error by 39% for a 12-bit multiplier compared with the radix-4 direct truncated multiplier. Results also demonstrate that, with the probabilistic estimation technique applied to the fixed-width radix-8 Booth multiplier, there is a reduction of 25% in the maximum absolute error, 13.4% reduction in the average error, and 25.13% reduction in the mean square error have been realized compared with the existing fixed-width radix-4 Booth multiplier with probabilistic estimation technique. Standard EDA design tools are used for simulations.

This paper was recommended by Regional Editor Tongquan Wei.

Keywords:

References

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