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Silent Data Corruption by 10× Test Escapes Threatens Reliable Computing

Subhasish Mitra

Subho Banerjee

Martin Dixon

Rama Govindaraju

Peter Hochschild

Eric Liu

Bharath Parthasarathy

Parthasarathy Ranganathan

IEEE Design & Test (2025) (to appear)

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Abstract

Too many defective compute chips are escaping today’s manufacturing tests – at least an order of magnitude more than industrial targets across all compute chip types in data centers. Silent data corruptions (SDCs) caused by test escapes, when left unaddressed, pose a major threat to reliable computing. We present a three-pronged approach outlining future directions for overcoming test escapes: (a) Quick diagnosis of defective chips directly from system-level incorrect behaviors. Such diagnosis is critical for gaining insights into why so many defective chips escape existing manufacturing testing. (b) In-field detection of defective chips. (c) New test experiments to understand the effectiveness of new techniques for detecting defective chips. These experiments must overcome the drawbacks and pitfalls of previous industrial test experiments and case studies.