Abstract

Excessive dynamic voltage drop in the power supply rails during test mode is known to result in false failures and impact yield when testing devices that use low-cost wire-bond packages. Identifying and debugging such test failures is a complex and effort-intensive process, especially when scan compression is involved. From a design cycle-tune view point, it is best to avoid this problem by generating "power-safe" scan patterns. The generation of power-safe patterns must take into consideration the DFT architecture, physical design, tuning and power constraints. In this paper, the authors propose such a framework and show experimental results on some benchmark circuits. The framework can address a non-uniform power grid and region-based power constraints. The authors show that glitching activity on nodes must be considered in order to correctly handle constraints on instantaneous peak power. The framework includes a power profiler that can analyze a pattern source for violations and a PODEM-based pattern generation engine for generating power-safe patterns.