Fine-grained Adaptive Testing Based on Quality Prediction

ACM Trans. Design Autom. Electr. Syst. Pub Date : 2020-10-02 DOI:10.1145/3385261

Mengyun Liu, Renjian Pan, Fangming Ye, Xin Li, K. Chakrabarty, Xinli Gu

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引用次数: 8

Abstract

The ever-increasing complexity of integrated circuits inevitably leads to high test cost. Adaptive testing provides an effective solution for test-cost reduction; this testing framework selects the important test items for each set of chips. However, adaptive testing methods designed for digital circuits are coarse-grained, and they are targeted only at systematic defects. To incorporate fabrication variations and random defects in the testing framework, we propose a fine-grained adaptive testing method based on machine learning. We use the parametric test results from the previous stages of test to train a quality-prediction model for use in subsequent test stages. Next, we partition a given lot of chips into two groups based on their predicted quality. A test-selection method based on statistical learning is applied to the chips with high predicted quality. An ad hoc test-selection method is proposed and applied to the chips with low predicted quality. Experimental results using a large number of fabricated chips and the associated test data show that to achieve the same defect level as in prior work on adaptive testing, the fine-grained adaptive testing method reduces test cost by 90% for low-quality chips and up to 7% for all the chips in a lot.

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基于质量预测的细粒度自适应测试

集成电路的复杂性日益增加，必然导致测试成本的提高。自适应测试为降低测试成本提供了有效的解决方案;该测试框架为每组芯片选择重要的测试项目。然而，为数字电路设计的自适应测试方法是粗粒度的，它们只针对系统缺陷。为了将制造变化和随机缺陷纳入测试框架，我们提出了一种基于机器学习的细粒度自适应测试方法。我们使用测试前一阶段的参数测试结果来训练质量预测模型，以便在随后的测试阶段中使用。接下来，我们根据芯片的预测质量将它们分成两组。将基于统计学习的测试选择方法应用于预测质量较高的芯片。提出了一种特殊的测试选择方法，并应用于预测质量较低的芯片。利用大量已加工芯片和相关测试数据进行的实验结果表明，细粒度自适应测试方法在达到与先前自适应测试相同的缺陷水平的情况下，可将低质量芯片的测试成本降低90%，将大量芯片的测试成本降低7%。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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ACM Trans. Design Autom. Electr. Syst.

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