Adaptive low-error fixed-width Booth multipliers

Min An Song; Lan Da Van; Sy Yen Kuo

doi:10.1093/ietfec/e90-a.6.1180

Adaptive low-error fixed-width Booth multipliers

Min An Song^*, Lan Da Van, Sy Yen Kuo

^*Corresponding author for this work

Research output: Contribution to journal › Journal Article › peer-review

42 Scopus citations

Abstract

In this paper, we propose two 2's-complement fixed-width Booth multipliers that can generate an n-bit product from an n-bit multiplicand and an n-bit multiplier. Compared with previous designs, our multipliers have smaller truncation error, less area, and smaller time delay in the critical paths. A four-step approach is adopted to search for the best errorcompensation bias in designing a multiplier suitable for VLSI implementation. Last but not least, we show the superior capability of our designs by inscribing it in a speech signal processor. Simulation results indicate that this novel design surpasses the previous fixed-width Booth multiplier in the precision of the product. An average error reduction of 65-84% compared with a direct-truncation fixed-width multiplier is achieved by adding only a few logic gates.

Original language	English
Pages (from-to)	1180-1187
Number of pages	8
Journal	IEICE Transactions on Fundamentals of Electronics, Communications and Computer Sciences
Volume	E90-A
Issue number	6
DOIs	https://doi.org/10.1093/ietfec/e90-a.6.1180
State	Published - 06 2007
Externally published	Yes

Keywords

Digital signal processing
Fixed-width Booth multiplier
VLSI

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10.1093/ietfec/e90-a.6.1180

Cite this

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title = "Adaptive low-error fixed-width Booth multipliers",

abstract = "In this paper, we propose two 2's-complement fixed-width Booth multipliers that can generate an n-bit product from an n-bit multiplicand and an n-bit multiplier. Compared with previous designs, our multipliers have smaller truncation error, less area, and smaller time delay in the critical paths. A four-step approach is adopted to search for the best errorcompensation bias in designing a multiplier suitable for VLSI implementation. Last but not least, we show the superior capability of our designs by inscribing it in a speech signal processor. Simulation results indicate that this novel design surpasses the previous fixed-width Booth multiplier in the precision of the product. An average error reduction of 65-84\% compared with a direct-truncation fixed-width multiplier is achieved by adding only a few logic gates.",

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AU - Van, Lan Da

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AB - In this paper, we propose two 2's-complement fixed-width Booth multipliers that can generate an n-bit product from an n-bit multiplicand and an n-bit multiplier. Compared with previous designs, our multipliers have smaller truncation error, less area, and smaller time delay in the critical paths. A four-step approach is adopted to search for the best errorcompensation bias in designing a multiplier suitable for VLSI implementation. Last but not least, we show the superior capability of our designs by inscribing it in a speech signal processor. Simulation results indicate that this novel design surpasses the previous fixed-width Booth multiplier in the precision of the product. An average error reduction of 65-84% compared with a direct-truncation fixed-width multiplier is achieved by adding only a few logic gates.

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Adaptive low-error fixed-width Booth multipliers

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Keywords

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