Testing iterative logic arrays for delay faults with a constant number of patterns

Abstract

Iterative logic arrays (ILAs) are widely used in many applications, e.g., general-purpose processors, digital signal processors, and embedded processors. Owing to the advanced VLSI technology, new defect mechanisms exist in the fabricated circuits. In order to ascertain the quality of manufactured products, the traditional single cell fault model is not sufficient. Therefore, more realistic fault models such as sequential fault models and delay fault models should also be targeted. A cell delay fault occurs if and only if an input transition cannot be propagated to the cell's output through a path in the cell in a specified clock period. It has been shown that all SIC (single input change) pairs of a circuit are sufficient to detect all robustly detectable path delay faults within the circuit. We extend the concept of SIC pairs for iterative logic arrays. We say that an ILA is C-testable for cell delay faults if it is possible to apply all SIC (single input change) pairs to every cell of the array in such a way that the number of test pairs for the array is a constant. Necessary conditions for sending this test set to each cell in the array and propagating faulty effects to the primary outputs are derived. An efficient algorithm is also presented to obtain such a test sequence. We use the pipelined array multiplier as an example to illustrate our approach. The number of test pairs for completely testing of the array is only 80. Moreover, the hardware overhead to make it delay fault testable is about 6%.