Title :
Static timing analysis based circuit-limited-yield estimation
Author :
Gattiker, Anne ; Nassif, Sani ; Dinakar, Rashmi ; Long, Chris
Abstract :
This paper presents a computationally efficient means for estimating parametric timing yield and guiding robust design-for-quality in the presence of manufacturing and operating environment variations. Computational efficiency is achieved by basing the proposed methodology on a post-processing step applied to the report generated as a by-product of static timing analysis. Efficiency is also ensured by exploiting the fact that for small processing/environment variations, a linear model is adequate for capturing the resulting delay change. Meaningful design guidance is achieved by analyzing the timing-related influence of variations on a path-by-path basis, allowing designers to perform a quality-oriented design pass focused on key paths. A coherent strategy is provided to handle both die-to-die and within-die variations. Examples from a PowerPC microprocessor illustrate the methodology and its capabilities.
Keywords :
integrated circuit design; integrated circuit modelling; integrated circuit yield; microprocessor chips; timing; PowerPC microprocessor; circuit-limited-yield estimation; computational efficiency; computationally efficient means; delay change; die-to-die variations; linear model; operating environment variations; path-by-path basis; post-processing step; quality-oriented design pass; robust design-for-quality; static timing analysis; within-die variations; Circuit analysis; Computational efficiency; Computer aided manufacturing; Delay; Microprocessors; Performance analysis; Pulp manufacturing; Robustness; Timing; Yield estimation;
Conference_Titel :
Circuits and Systems, 2002. ISCAS 2002. IEEE International Symposium on
Print_ISBN :
0-7803-7448-7
DOI :
10.1109/ISCAS.2002.1010645
