Non-scan design-for-testability techniques for sequential circuits

Abstract

Recent studies show that a stuck-at test applied at the operational speed of the circuit identifies more defective chips than a test having the same fault coverage but applied at a lower speed. In this work, we investigate various design-for-testability (DFT) techniques for sequential circuits which permit at-speed application of tests while providing for very high fault coverage. The method involves parallel loading of flip-flops in test mode for enhanced controllability combined with probe point insertion for enhanced observability. Selection of candidate flip-flops and probe points is determined automatically by our OP US-NS tool. Fault coverage and ATG effectiveness improved to greater than 96% and 99. 7%, respectwely, for the ISCAS89 sequential benchmark circuits studied when these nonscan DFT techniques were used.