Optimized architecture for Floating Point computation Unit

2013 International Conference on Emerging Trends in VLSI, Embedded System, Nano Electronics and Telecommunication System (ICEVENT) Pub Date : 2013-04-11 DOI:10.1109/ICEVENT.2013.6496587

Harish Anand Ti, D. Vaithiyanathan, R. Seshasayanan

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引用次数: 7

Abstract

As floating point operations are complex, hence its implementation in Field Programmable Gate Array (FPGAs) consumes large amount of resources. FPGAs becomes inefficient if Floating Point Units (FPUs) are unutilized, to overcome this issue, a novel architecture is proposed in this paper for optimizing the floating point computation units in hybrid FPGAs in terms of achieving a better reduction in both area and power. The proposed architecture involves an algorithmic (logarithmic) approach for computing floating point numerical operations. It performs all the four basic arithmetic operations using simple hardware like adders, look up tables and interpolation steps. This methodology is used to evaluate a variety of FPU architecture optimizations. The model is being evaluated by comparing with the existing architectures like embedded FPUs and other FPU units in the FPGAs in terms of area, power, speed and high throughput. The simulation results of our model in cadence encounter tool shows the proposed architecture scales nearly 28 percent area and consumes 36 percent less power than existing FPUs. And also our method scales very well with an increase in required accuracy compared to the existing techniques.

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浮点计算单元的优化架构

由于浮点运算比较复杂，因此在fpga (Field Programmable Gate Array，现场可编程门阵列)中实现浮点运算需要消耗大量的资源。如果浮点单元(fpu)未被利用，fpga会变得效率低下，为了克服这一问题，本文提出了一种新的架构来优化混合fpga中的浮点计算单元，以实现更好的面积和功耗降低。所提出的体系结构涉及一种计算浮点数值运算的算法(对数)方法。它使用简单的硬件(如加法器、查找表和插值步骤)执行所有四种基本算术运算。该方法用于评估各种FPU架构优化。通过与现有架构(如嵌入式FPU和fpga中的其他FPU单元)在面积、功率、速度和高吞吐量方面进行比较，对该模型进行了评估。我们的模型在节奏遭遇工具中的仿真结果表明，所提出的架构比现有的fpu扩展了近28%的面积，功耗降低了36%。而且，与现有技术相比，我们的方法可以很好地提高所需的精度。

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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2013 International Conference on Emerging Trends in VLSI, Embedded System, Nano Electronics and Telecommunication System (ICEVENT)

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