Logic BIST With Capture-Per-Clock Hybrid Test Points

Logic built-in self-test (LBIST) is now increasingly used with on-chip test compression as a complementary solution for in-system test, where high quality, low power, low silicon area, and most importantly short test application time are key factors affecting ICs targeted for safety-critical systems. Test points, common in LBIST-ready designs, can help to reduce test time and the overall silicon overhead so that one can get desired test coverage with the minimal number of patterns. Typically, LBIST test points are dysfunctional when enabled in an ATPG-based test compression mode. Similarly, test points used to reduce ATPG pattern counts (PCs) cannot guarantee desired random testability. In this paper, we present a hybrid test point technology designed to reduce deterministic PCs and to improve fault detection likelihood by means of the same minimal set of test points. The hybrid test points are subsequently deployed in a scan-based LBIST scheme addressing stringent test requirements of certain application domains such as the automotive electronics market. These requirements, largely driven by safety standards, are met by significantly reducing test application time while preserving the high fault coverage. The new scheme is a combination of pseudorandom test patterns delivered in a test-per-clock fashion through conventional scan chains and per-cycle-driven hybrid observation test points that capture faulty effects every shift cycle into dedicated scan chains. Their content is gradually shifted into a compactor shared with the remaining chains that deliver responses once a test pattern has been shifted-in. Experimental results obtained for industrial designs confirm feasibility of the new schemes, and they are reported herein.