Approximation Logic for Multiplication Through Partial Product Perforation

2019 3rd International Conference on Electronics, Materials Engineering & Nano-Technology (IEMENTech) Pub Date : 2019-08-01 DOI:10.1109/IEMENTech48150.2019.8981043

V. B. Cousik, N. S. Murty

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引用次数: 1

Abstract

The partial product perforation or truncation methods for approximate multiplication, though have well defined error boundaries are not independent of the number of bits in the number being perforated. In this paper the partial product perforation from Most Significant Bit (MSB) technique is proposed. In this method the error boundaries are well defined and are independent of the number of bits in the number which is being perforated. As the error boundaries are well defined, this technique can be put to practical use in the applications which are error tolerant. This technique optimizes the generation of partial products as per the error tolerance of the application. As the partial product generation is optimized, the number of full adders being used is also optimized and hence the power consumption and delay are also optimized. A 32 bit multiplier for 1% error tolerance, the proposed method gives 75% and 35% reduction in power and delay respectively as compared to the accurate multiplier.

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部分积穿孔乘法的近似逻辑

近似乘法的部分积穿孔或截断方法，虽然有很好的定义的误差边界，但并不独立于被穿孔数中的位数。本文提出了基于最有效位(MSB)技术的部分积射孔方法。在这种方法中，错误边界被很好地定义，并且与被穿孔的数字中的位数无关。由于错误边界的明确，该技术可以在容错应用中得到实际应用。该技术根据应用的误差容忍度优化了部分产品的生成。随着部分积生成的优化，所使用的全加法器的数量也得到了优化，因此功耗和延迟也得到了优化。该方法采用32位乘法器，误差容忍度为1%，与精确乘法器相比，功耗和延迟分别降低75%和35%。

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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2019 3rd International Conference on Electronics, Materials Engineering & Nano-Technology (IEMENTech)

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