并发内建自检技术的实现与分析

[1988] The Eighteenth International Symposium on Fault-Tolerant Computing. Digest of Papers Pub Date : 1988-06-27 DOI:10.1109/FTCS.1988.5315

Rajiv Sharma, K. Saluja

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引用次数: 44

摘要

提出了一种内置并发自检(BICST)技术，可以在组合逻辑电路正常工作的同时对其进行测试。他们还引入了在相同电路之间共享测试硬件的概念，以减少总体面积开销。他们在CMOS技术中实现了具有在线测试能力的ALU(算术逻辑单元)的设计。用于12位ALU的额外硬件占总芯片面积的19%，并且不会对ALU的操作造成任何时间开销。开销随着ALU大小的增加而减少。作者定义了一些评估BICST技术性能的指标，并讨论了它们的计算方法，包括仿真和分析结果。除了检测永久性故障外，BICST技术还可用于检测间歇性和瞬态故障。提出了一些间歇故障检测和暂态故障覆盖率计算的方法。

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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An implementation and analysis of a concurrent built-in self-test technique

The authors propose a built-in concurrent self-test (BICST) technique for testing combinational logic circuits concurrently with their normal operation. They also introduce a concept of sharing the test hardware between identical circuits to reduce the overall area overhead. They implemented this technique in the design of an ALU (arithmetic logic unit) with online test capability in CMOS technology. The additional hardware used for a 12-bit ALU was 19% of the total chip area, and it did not impose any timing overhead on the operation of the ALU. The overhead decreases with an increase in the size of the ALU. The authors define some measures for evaluating the performance of the BICST technique and discuss methods for their computation and include both simulation and analytical results. In addition to detecting permanent faults, the BICST technique can also be used for detecting intermittent and transient faults. The authors propose some methods for detecting intermittent faults and for computing the transient fault coverage.<>

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来源期刊

[1988] The Eighteenth International Symposium on Fault-Tolerant Computing. Digest of Papers

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