Towards dark silicon era in FPGAs using complementary hard logic design

2014 24th International Conference on Field Programmable Logic and Applications (FPL) Pub Date : 2014-10-20 DOI:10.1109/FPL.2014.6927504

A. Ahari, Behnam Khaleghi, Zahra Ebrahimi, H. Asadi, M. Tahoori

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引用次数: 13

Abstract

While the transistor density continues to grow exponentially in Field-Programmable Gate Arrays (FPGAs), the increased leakage current of CMOS transistors act as a power wall for the aggressive integration of transistors in a single die. One recently trend to alleviate the power wall in FPGAs is to turn off inactive regions of the silicon die, referred to as dark silicon. This paper presents a reconfigurable architecture to enable effective fine-grained power gating of unused Logic Blocks (LBs) in FPGAs. In the proposed architecture, the traditional soft logic is replaced with Mega Cells (MCs), each consists of a set of complementary Generic Reconfigurable Hard Logic (GRHL) and a conventional Look-Up Table (LUT). Both GRHL cells and LUTs can be power gated and turned off by controlling configuration bits. In the proposed MC, only one cell is active and the others are turned off. Experimental results on MCNC benchmark suite reveal that the proposed architecture reduces the critical path delay, power, and Power Delay Product (PDP) of LBs up to 5.3%, 30.4%, and 28.8% as compared to the equivalent LUT-based architecture.

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迈向暗硅时代的fpga采用互补硬逻辑设计

当现场可编程门阵列(fpga)的晶体管密度继续呈指数级增长时，CMOS晶体管泄漏电流的增加就像一个电源墙，阻碍了晶体管在单个芯片中的积极集成。最近缓解fpga中功率墙的一个趋势是关闭硅芯片的非活性区域，称为暗硅。本文提出了一种可重构架构，可以对fpga中未使用的逻辑块(LBs)进行有效的细粒度功率门控。在该架构中，传统的软逻辑被Mega cell (MCs)所取代，每个MCs由一组互补的通用可重构硬逻辑(GRHL)和一个传统的查找表(LUT)组成。GRHL单元和lut都可以通过控制配置位进行电源门控和关闭。在提议的MC中，只有一个单元处于活动状态，其他单元处于关闭状态。在MCNC基准测试套件上的实验结果表明，与等效的基于lutt的架构相比，该架构可将关键路径延迟、功率和功率延迟乘积(PDP)分别降低5.3%、30.4%和28.8%。

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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2014 24th International Conference on Field Programmable Logic and Applications (FPL)

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