Improved Approximate Multipliers for Single-Precision Floating-Point Hardware Design

2022 IEEE 13th Latin America Symposium on Circuits and System (LASCAS) Pub Date : 2022-03-01 DOI:10.1109/LASCAS53948.2022.9789077

Patrícia U. L. da Costa, P. Pereira, B. Abreu, Guilherme Paim, E. Costa, S. Bampi

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引用次数: 4

Abstract

This paper reveals that state-of-the-art integer approximate multipliers (AxMs) present dispensable blocks when specifically embedded within a floating-point (FP) architecture. This paper proposes and implements arithmetic simplifications that significantly improve four state-of-the-art AxMs for FP. The results for 32-bit FP (FP-32) show that our improved 24-bit integer AxMs (i.e., specific for FP) reduce area from about 4.2x up to 12.9x in four different AxMs when compared with the original 24-bit AxM generic integer multiplier. We also perform an AxC design space exploration (DSE) of FP-32 Least Mean Squares Adaptive Filters (LMS-AF) architectures employing the four improved AxM proposals. We present quality-energy and -area DSE trade-offs in an approximate FP-32 LMS-AF kernel, in terms of Pareto fronts, showing that we can still maintain a fully functional harmonics elimination. Pareto front total energy reduction ranges from 43.4 % (1.27x) to 70.3% (3.37x) w.r.t. the precise multiplier.

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单精度浮点硬件设计的改进近似乘法器

本文揭示了最先进的整数近似乘法器(axm)在具体嵌入浮点(FP)架构时存在可缺性块。本文提出并实现了算法简化，显著改进了FP的四个最先进的axm。32位FP (FP-32)的结果表明，与原始的24位AxM通用整数乘法器相比，我们改进的24位整数AxM(即针对FP的)在四个不同的AxM中将面积从4.2倍减少到12.9倍。我们还使用四种改进的AxM方案对FP-32最小均方自适应滤波器(LMS-AF)架构进行了AxC设计空间探索(DSE)。在帕累托前沿方面，我们在近似FP-32 LMS-AF内核中提出了质量-能量和面积DSE权衡，表明我们仍然可以保持全功能的谐波消除。帕累托前总能量减少范围从43.4%(1.27倍)到70.3%(3.37倍)。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2022 IEEE 13th Latin America Symposium on Circuits and System (LASCAS)

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