Title :
Efficient approaches to low-cost high-fault coverage VLSI BIST designs
Author :
Chen, Chien-In Henry
Author_Institution :
Dept. of Electr. Eng., Wright State Univ., Dayton, OH, USA
fDate :
1/1/1998 12:00:00 AM
Abstract :
This work introduces a built-in self-test (BIST) design methodology that can sequentially test large very large scale integrated (VLSI) circuits with very high fault coverage. The proposed techniques, circular BIST ((BIST) and (BIST with pseudopartial scan (PPSCAN), are modeled after the principles of the circular self-test path (CSTP). The basis of this method is to trade a minimal increase in hardware overhead for a large increase in fault coverage. It is shown that this technique yields a much higher fault coverage with reasonable time and test vector length when compared with existing sequential test methods. The effectiveness of the technique has been demonstrated by applying it to practical VLSI circuits, which include: 1) the system control coprocessor (CP0) of MIPS 3000 central processing unit (CPU) core and 2) the SIMD graphic engine, namely, enhanced memory chip (EMC). The BIST results show that (BIST and its derivative (BIST with pseudopartial scan (PPSCAN) are feasible for practical VLSI designs and generate BIST with high fault coverage and low overhead
Keywords :
VLSI; automatic testing; built-in self test; design for testability; fault diagnosis; integrated circuit design; logic testing; MIPS 3000 central processing unit; SIMD graphic engine; VLSI BIST design; built-in self-test; circular BIST; effectiveness; enhanced memory chip; fault coverage; hardware overhead; memory cell; overhead; pseudopartial scan; register cell; sequential test; system control coprocessor; Automatic testing; Built-in self-test; Central Processing Unit; Centralized control; Circuit faults; Circuit testing; Design methodology; Hardware; Sequential analysis; Very large scale integration;
Journal_Title :
Aerospace and Electronic Systems, IEEE Transactions on
