Stuck-at fault

About: Stuck-at fault is a research topic. Over the lifetime, 9707 publications have been published within this topic receiving 160254 citations.

Fault Dictionary Based Scan Chain Failure Diagnosis

Abstract: In this paper, we present a fault dictionary based scan chain failure diagnosis technique. We first describe a technique to create small dictionaries for scan chain faults by storing differential signatures. Based on the differential signatures stored in a fault dictionary, we can quickly identify single stuck-at fault or timing fault in a faulty chain. We further develop a novel technique to diagnose some multiple stuck-at faults in a single scan chain. Comparing with fault simulation based diagnosis technique, the proposed fault dictionary based diagnosis technique is up to 130 times faster with same level of diagnosis accuracy and resolution.

An efficient test data reduction technique through dynamic pattern mixing across multiple fault models

Abstract: ATPG tool generated patterns are a major component of test data for large SOCs. With increasing sizes of chips, higher integration involving IP cores and the need for patterns targeting multiple fault models for better defect coverage in newer technologies, the issues of adequate coverage and reasonable test data volume and application time dominate the economics of test. We address the problem of generating compact set of test patterns across multiple fault models. Traditional approaches use separate ATPG for each fault models and minimize patterns either during pattern generation through static or dynamic compaction, or after pattern generation by simulating all patterns over all fault models for static compaction. We propose a novel ATPG technique where all fault models of interest are concurrently targeted in a single ATPG run. Patterns are generated in small intervals, each consisting of 16, 32 or 64 patterns. In each interval fault model specific ATPG setups generate separate pattern sets for their respective fault model. An effectiveness criterion then selects exactly one of those pattern sets. The selected set covers untargeted faults that would have required the most additional patterns. Pattern generation intervals are repeated until required coverage for faults of all models of interest is achieved. The sum total of all selected interval pattern sets is the overall test set for the DUT. Experiments on industrial circuits show pattern count reductions of 21% to 68%. The technique is independent of any special ATPG tool or scan compression technique and requires no change or additional support in an existing ATPG system.

An Accurate Fault Location Algorithm For Double-Circuit Transmissisn Systems

Abstract: This paper describes an accurate fault locatio11 algorithm based on sequence current distribution facbrs for

Adaptive techniques for improving delay fault diagnosis

Abstract: This paper presents adaptive techniques for improving delay fault diagnosis. These techniques reduce the search space for direct probing which can save a lot of time during failure analysis. Given a set of two-pattern tests that resulted in faulty output responses, a procedure for deriving additional two-pattern tests that will improve the diagnostic resolution of delay faults is described. Two new techniques based on adjacency testing and delay-size bounding are presented. These techniques can be used to greatly reduce the number of suspect lines and thereby provide a more precise diagnosis that is valid for either single or multiple delay faults. Experimental results are shown indicating that the number of suspects can be reduced dramatically for both single and multiple delay faults.

Spectral Fault Signatures for Single Stuck-At Faults in Combinational Networks

Abstract: A method is described for the derivation of fault signatures for the detection of stuck-at faults in single-output combinational networks. These signatures consist of a set of values derived from the network. Any single stuck-at fault causes at least one value to change. The fault signatures developed are a generalization of syndrome testing. The technique is developed in the Rademacher-Walsh spectral domain but is easily implemented using conters and basic gates.