SOC test planning using virtual test access architectures

Recent advances in tester technology have led to automatic test equipment (ATE) that can operate at up to gigahertz speeds. However, system-on-chip (SOC) scan chains are typically run at lower frequencies, e.g., 10-50 MHz. The use of high-speed ATE channels to drive slower scan chains leads to an underutilization of resources, thereby resulting in an increase in SOC testing time. We present a new test planning technique to reduce the testing time and test cost by matching high-speed ATE channels to slower scan chains using the concept of virtual test access architectures. We also present a new test access mechanism (TAM) optimization framework based on Lagrange multipliers and analyze the impact of virtual TAMs on the overall SOC test power consumption for one of the ITC´02 benchmarks. Experimental results for TAM optimization based on Lagrange multipliers and virtual TAMs are presented for three industrial circuits from the set of ITC´02 SOC test benchmarks.