基于因果推理的模拟电路验证方法

2015 International Conference on Synthesis, Modeling, Analysis and Simulation Methods and Applications to Circuit Design (SMACD) Pub Date : 2015-09-01 DOI:10.1109/SMACD.2015.7301711

Fanshu Jiao, A. Doboli

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引用次数: 3

摘要

本文提出了一种基于因果推理的模拟电路验证方法。为了验证模拟电路，流程从挖掘产生电路的因果推理步骤(设计计划)开始，包括起始想法、设计步骤顺序及其论证[1]。然后，用理想放大器模型替换相关器件，分别验证了与初始思想和设计阶跃序列相对应的拓扑结构。通过Spectre仿真对电路性能进行了评估。比较仿真结果可以揭示某些初始想法或设计步骤的不正确的功能问题和/或性能缺陷(负面原因)，这些问题可能在设计过程中被忽略。本文讨论了在0.2 μm CMOS技术上实现的三种运算放大器设计，以说明验证方法。

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A causal reasoning-based approach for analog circuit verification

This paper proposes a novel analog circuit verification approach using causal reasoning. To verify analog circuits, the flow begins with mining the causal reasoning steps (design plan) that produced the circuit, including starting ideas, design step sequence, and their justification [1]. Then, topological structures corresponding to the starting ideas and design step sequences are verified individually by replacing the related devices with ideal amplifier model. Circuit performance is evaluated through Spectre simulation. Comparing simulation results reveals incorrect functional issues and/or performance drawbacks (negative causes) of certain starting ideas or design steps, which might have been omitted during the design process. The paper discusses three operational amplifier designs realized in 0.2-μm CMOS technology to illustrate the verification approach.

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2015 International Conference on Synthesis, Modeling, Analysis and Simulation Methods and Applications to Circuit Design (SMACD)

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