基于FPGA和ASIC的双精度全可编程计算单元设计

2020 International Conference on Computing, Electronics & Communications Engineering (iCCECE) Pub Date : 2020-08-17 DOI:10.1109/iCCECE49321.2020.9231146

M. Sajjad, M. Yusoff, Muhammad Ahmed

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引用次数: 3

摘要

许多高精度传感器的传感算法都是在现场可编程门阵列(fpga)中实现的，因为这种器件满足了大部分的算法要求。但是为了提高传感器的性能，通常需要根据环境变化来补偿它们的输出。这种补偿要求在一些与环境变化相对应的变量中实现多项式函数。本文提出了一种低成本的双精度、可重用和灵活的计算单元设计，用于在数字硬件中实现这些多项式函数。该设计可以直接用于任何FPGA，甚至用于专用集成电路(ASIC)的开发。在ASIC设计的情况下，它还具有处理传感器到传感器多项式变化所需的灵活性。通过对不同fpga和350nm工艺节点ASIC的仿真验证了该设计。该设计还在Spartan-6 FPGA上实现，用于实时补偿传感器输出。

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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Design of Double-Precision Fully-Programmable Computational Unit for FPGA and ASIC

The sensing algorithm of many high-precision sensors is implemented in Field Programmable Gate Arrays (FPGAs) because such devices meet most of the algorithm requirements. But to enhance sensors’ performance, it is often required to compensate for their output against environmental variations. This compensation requires implementing polynomial functions in some variables corresponding to the environmental variations. This paper presents a low-cost design for double-precision, reusable, and flexible computational unit for implementing such polynomial functions in digital hardware. The design can be directly used for any FPGA and even for Application-Specific Integrated Circuit (ASIC) development. In the case of ASIC design, it also features the required flexibility to handle sensor to sensor polynomial variations. The design has been verified through simulation for different FPGAs and 350nm technology node ASIC. The design has also been implemented in Spartan-6 FPGA to compensate sensors’ output in real-time.

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来源期刊

2020 International Conference on Computing, Electronics & Communications Engineering (iCCECE)

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