S. Sur-Kolay, M. Roncken, K. Stevens, P. P. Chaudhuri, Rob Roy
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引用次数: 19
摘要
在非常高的频率下,异步电路的主要潜力是没有时钟倾斜,并通过它更好地利用相对时序关系。本文介绍了一种用于异步顺序电路中卡滞和门延迟故障的门级故障模拟器Fsimac。Fsimac不仅可以评估组合逻辑和典型的异步门(如Muller c -element),还可以评估在高速设计中广泛应用的复杂多米诺门。我们设计的反馈回路检测算法是为了使模拟展开电路的迭代次数最小化。我们使用最小-最大时序分析来计算信号延迟的界限。通过将主输出的逻辑值与无故障设计中的相应值进行比较来检测卡滞故障。对于延迟故障,我们还比较了主输出信号的最小-最大时间戳。Fsimac报告的由元胞自动机生成的伪随机测试的故障覆盖率显示了一些非常好的结果,但也指出了需要更具体模式的测试漏洞。我们打算使用Fsimac来设计更有效的CA-BIST。
Fsimac: a fault simulator for asynchronous sequential circuits
At very high frequencies, the major potential of asynchronous circuits is absence of clock skew and, through that, better exploitation of relative timing relations. This paper presents Fsimac, a gate-level fault simulator for stuck-at and gate-delay faults in asynchronous sequential circuits. Fsimac not only evaluates combinational logic and typical asynchronous gates such as Muller C-elements, but also complex domino gates, which are widely used in high-speed designs. Our algorithm for desecting feedback loops is designed so as to minimize the iterations for simulating the unfolded circuit. We use min-max timing analysis to compute the bounds on the signal delays. Stuck-at faults are detected by comparing logic values at the primary outputs against the corresponding values in the fault-free design. For delay faults, we additionally compare min-max rime stamps for primary output signals. Fault coverage reported by Fsimac for pseudo-random tests generated by Cellular Automata show some very good results, but also indicate test holes for which more specific patterns are needed. We intend to deploy Fsimac for designing more effective CA-BIST.
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