A scan segmentation architecture for power controllability and reduction

2015 28th IEEE International System-on-Chip Conference (SOCC) Pub Date : 2015-09-01 DOI:10.1109/SOCC.2015.7406961

Z. Jiang, D. Xiang, Kele Shen

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引用次数: 2

Abstract

With the chip size entering the micro-nano level, the increasing power consumption during the chip testing process becomes the bottleneck of chip production and testing. Prior work has been mainly focused on reducing power dissipation in either shift cycle or capture cycle, however, there has been limited work on reducing the peak power in both shift and capture cycles at the same time. Moreover, there has been no work on the problem of capture power controllability. This paper proposes a new power-aware scan segment architecture, which can accurately control the power of shift and capture cycles at the same time with small area overhead. Meanwhile, we devise sophisticated algorithms of dependency checking and scan segments partitioning, which can directly reduce simultaneously switching activity of flip-flops by iterative optimizing scan segments grouping. To the best of our knowledge, this paper is the first of its kind to study the problem of power controllability considering both structure dependency and clock trees' impact. Extensive experiments have been performed on reference circuit ISCAS89 and IWLS2005 to verify the effectiveness of the proposed architecture.

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一种可控制和降低功率的扫描分割结构

随着芯片尺寸进入微纳级，芯片测试过程中不断增加的功耗成为芯片生产和测试的瓶颈。先前的工作主要集中在降低移位周期或捕获周期的功耗上，然而，在同时降低移位和捕获周期的峰值功率方面的工作有限。此外，还没有关于捕获功率可控性问题的研究。本文提出了一种新的功率感知扫描段结构，该结构能以较小的面积开销同时精确控制移位和捕获周期的功率。同时，我们设计了复杂的依赖检查和扫描段划分算法，通过迭代优化扫描段分组，直接减少触发器的同步切换活动。据我们所知，本文是第一个同时考虑结构依赖和时钟树影响的电力可控性问题的研究。在参考电路ISCAS89和IWLS2005上进行了大量的实验，以验证所提出架构的有效性。

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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2015 28th IEEE International System-on-Chip Conference (SOCC)

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