From Specification to Silicon: Towards Analog/Mixed-Signal Design Automation using Surrogate NN Models with Transfer Learning

2021 IEEE/ACM International Conference On Computer Aided Design (ICCAD) Pub Date : 2021-11-01 DOI:10.1109/ICCAD51958.2021.9643445

Juzheng Liu, Shiyu Su, Meghna Madhusudan, Mohsen Hassanpourghadi, Samuel Saunders, Qiaochu Zhang, Rezwan A. Rasul, Yaguang Li, Jiang Hu, A. Sharma, S. Sapatnekar, R. Harjani, Anthony Levi, S. Gupta, M. Chen

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引用次数: 10

Abstract

We propose a complete analog mixed-signal circuit design flow from specification to silicon with minimum human-in-the-loop interaction, and verify the flow in a 12nm FinFET CMOS process. The flow consists of three key elements: neural network (NN) modeling of the parameterized circuit component, a search algorithm based on NN models to determine its sizing, and layout automation. To reduce the required training data for NN model creation, we utilize transfer learning to improve the NN accuracy from a relatively small amount of post-layout/silicon data. To prove the concept, we use a voltage-controlled oscillator (VCO) as a test vehicle and demonstrate that our design methodology can accurately model the circuit and generate designs with a wide range of specifications. We show that circuit sizing based on the transfer learned NN model from silicon measurement data yields the most accurate results.

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从规格到硅:使用迁移学习代理神经网络模型实现模拟/混合信号设计自动化

我们提出了一个完整的模拟混合信号电路设计流程，从规格到硅，以最小的人机交互，并在12nm FinFET CMOS工艺中验证了该流程。该流程包括三个关键要素:参数化电路元件的神经网络建模，基于神经网络模型的搜索算法确定其尺寸，以及布局自动化。为了减少神经网络模型创建所需的训练数据，我们利用迁移学习从相对少量的布局后/硅数据中提高神经网络的准确性。为了证明这一概念，我们使用压控振荡器(VCO)作为测试工具，并证明我们的设计方法可以准确地模拟电路并生成具有广泛规格的设计。我们表明，基于从硅测量数据迁移学习的神经网络模型的电路尺寸产生最准确的结果。

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2021 IEEE/ACM International Conference On Computer Aided Design (ICCAD)

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