Virtual probe: A statistically optimal framework for minimum-cost silicon characterization of nanoscale integrated circuits

2009 IEEE/ACM International Conference on Computer-Aided Design - Digest of Technical Papers Pub Date : 2009-11-02 DOI:10.1145/1687399.1687481

Xin Li, Rob A. Rutenbar, R. D. Blanton

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引用次数: 51

Abstract

In this paper, we propose a new technique, referred to as virtual probe (VP), to efficiently measure, characterize and monitor both inter-die and spatially-correlated intra-die variations in nanoscale manufacturing process. VP exploits recent breakthroughs in compressed sensing [15]-[17] to accurately predict spatial variations from an exceptionally small set of measurement data, thereby reducing the cost of silicon characterization. By exploring the underlying sparse structure in (spatial) frequency domain, VP achieves substantially lower sampling frequency than the well-known (spatial) Nyquist rate. In addition, VP is formulated as a linear programming problem and, therefore, can be solved both robustly and efficiently. Our industrial measurement data demonstrate that by testing the delay of just 50 chips on a wafer, VP accurately predicts the delay of the other 219 chips on the same wafer. In this example, VP reduces the estimation error by up to 10× compared to other traditional methods. Categories and Subject Descriptors B.7.2 [Integrated Circuits]: Design Aids — Verification General Terms Algorithms

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虚拟探针:用于纳米级集成电路的最低成本硅表征的统计优化框架

在本文中，我们提出了一种新的技术，称为虚拟探针(VP)，以有效地测量、表征和监测纳米尺度制造过程中模具间和空间相关的模具内变化。VP利用压缩感知的最新突破[15]-[17]，从极小的测量数据集准确预测空间变化，从而降低硅表征的成本。通过探索(空间)频域的底层稀疏结构，VP实现了比众所周知的(空间)奈奎斯特率低得多的采样频率。此外，VP被表述为线性规划问题，因此可以鲁棒高效地求解。我们的工业测量数据表明，通过测试晶圆上仅50个芯片的延迟，VP可以准确预测同一晶圆上其他219个芯片的延迟。在这个例子中，与其他传统方法相比，VP将估计误差降低了10倍。B.7.2[集成电路]:设计辅助工具-验证通用术语算法

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