Can real-time systems benefit from dynamic partial reconfiguration?

2017 IEEE Nordic Circuits and Systems Conference (NORCAS): NORCHIP and International Symposium of System-on-Chip (SoC) Pub Date : 2017-10-01 DOI:10.1109/NORCHIP.2017.8124984

Luca Pezzarossa, Andreas Toftegaard Kristensen, Martin Schoeberl, J. Sparsø

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引用次数: 7

Abstract

In real-time systems, a solution where hardware accelerators are used to implement computationally intensive tasks can be easier to analyze, in terms of worst-case execution time (WCET), than a pure software solution. However, when using FPGAs, the amount and the complexity of the hardware accelerators are limited by the resources available. Dynamic partial reconfiguration (DPR) of FPGAs can be used to overcome this limitation by replacing the accelerators that are only required for limited amounts of time with new ones. This paper investigates the potential benefits of using DPR to implement hardware accelerators in real-time systems and presents an experimental analysis of the trade-offs between hardware utilization and WCET increase due to the reconfiguration time overhead of DPR. We also investigate the trade-off between the use of multiple specialized accelerators combined with DPR instead of the use of a more general accelerator. The results show that, for computationally intensive tasks, the use of DPR can lead to a more efficient use of the FPGA, while maintaining comparable computational performance.

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实时系统能从动态部分重构中获益吗?

在实时系统中，使用硬件加速器来实现计算密集型任务的解决方案在最坏情况执行时间(WCET)方面比纯软件解决方案更容易分析。然而，当使用fpga时，硬件加速器的数量和复杂性受到可用资源的限制。fpga的动态部分重构(DPR)可以通过用新加速器替换只需要有限时间的加速器来克服这一限制。本文研究了在实时系统中使用DPR实现硬件加速器的潜在好处，并对由于DPR的重新配置时间开销而导致的硬件利用率和WCET增加之间的权衡进行了实验分析。我们还研究了使用多个专用加速器与DPR相结合而不是使用更通用的加速器之间的权衡。结果表明，对于计算密集型任务，使用DPR可以更有效地使用FPGA，同时保持相当的计算性能。

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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2017 IEEE Nordic Circuits and Systems Conference (NORCAS): NORCHIP and International Symposium of System-on-Chip (SoC)

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