In this paper, we investigate the problem of computing a lower bound on the number of buffers required when given a maximum clock slew rate (or rise time) constraint and a predefined clock tree. Using generalized properties of published CMOS timing models, we formulate a novel nonlinear buffer insertion problem. Next, we derive an algorithm that bounds the capacitance for each buffer stage without sacrificing the generality of the timing models. With this capacitance bound we formulate a second linear buffer insertion problem, which we solve optimally in O(n) time. The basic formulation and algorithm are extended to include a skew upper bound constraint. Using these algorithms we propose further algorithmic extensions that allow area and phase delay tradeoffs. Our results are verified using SPICE3e2 simulations with MCNC MOSIS 2.0 /spl mu/ models and parameters. Experiments with these test cases show that the buffer insertion algorithms proposed herein can be used effectively for designs with high clock speeds and small skews.
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机译:在本文中,我们研究了在给定最大时钟摆率(或上升时间)约束和预定义时钟树的情况下,计算所需缓冲区数量下限的问题。使用已发布的CMOS时序模型的广义属性,我们制定了一个新颖的非线性缓冲区插入问题。接下来,我们导出一种算法,该算法在不牺牲时序模型的通用性的情况下限制了每个缓冲级的电容。在此电容范围内,我们制定了第二个线性缓冲器插入问题,可以在O(n)时间内最佳解决。基本公式和算法已扩展为包括偏斜上限约束。使用这些算法,我们提出了进一步的算法扩展,允许面积和相位延迟之间的折衷。我们的结果通过使用带有MCNC MOSIS 2.0 / spl mu /模型和参数的SPICE3e2仿真进行了验证。这些测试用例的实验表明,本文提出的缓冲区插入算法可有效地用于具有高时钟速度和较小偏斜的设计。
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