AI accelerators increasingly operate under tight power, thermal, voltage, and timing margins, making workload-dependent thermal nonuniformity an important reliability concern. In systolic AI accelerators, localized activity concentration can create spatially uneven thermal stress, but thermal or timing-exposure analysis alone does not determine whether such stress remains benign, becomes numerically masked, or propagates into silent corruption. This paper presents a cross-layer early-stage screening methodology for thermal nonuniformity-aware reliability analysis in systolic arrays. The framework links workload-aware activity extraction, relative power concentration modeling, diffusion-based thermal proxy analysis, an explicit thermal-to-timing stress abstraction, path class-aware corruption modeling, and clean/masked/silent outcome classification. The revised framework is formalized mathematically and evaluated across dense, low-dynamic-range, and sparse GEMM workloads under weight-stationary and output-stationary execution. To strengthen statistical and methodological confidence, the study includes 100-seed corruption reruns with Wilson confidence intervals, thermal scaling across 8×8, 16×16, and 32×32 arrays, calibration sensitivity, path weight sensitivity, component ablations, and preliminary compact thermal reference alignment. The results show that sparse workloads consistently produce the largest thermal spread across tested array sizes, while dense and low-dynamic-range workloads remain more spatially uniform. Under the default calibrated screening regime at 16×16, sparse output-stationary and sparse weight-stationary cases reach 49% and 40% silent corruption rates, respectively, while dense cases remain mostly clean or masked and low-dynamic-range cases remain largely clean. Sensitivity and ablation experiments show that the sparse workload risk is not caused by one isolated modeling component, although the masked/silent split depends on path class weighting and thermal diffusion assumptions. The main contribution is not signoff-accurate silicon failure prediction, but a reproducible screening front end for identifying workload, dataflow, and path class combinations that deserve deeper thermal, timing, RTL-level, and application-level validation.
Larisa Goffman-Vinopal (Sun,) studied this question.
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