Physically-Aware Analysis of Systematic Defects in Integrated Circuits

Tam, Wing Chiu; Blanton, R. D.

doi:10.1109/mdt.2012.2211093

Cited by 12 publications

(17 citation statements)

References 95 publications

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“…Failures due to other sources (e.g., random-spot contaminations, systematic defects, etc.) are assumed to have been already removed from the population of N failed chips using existing approaches [17][18][19]. This means that the failed-chip population can be distributed among the K rules.…”

Section: Rule-violation Typesmentioning

confidence: 99%

DREAMS: DFM Rule EvAluation using Manufactured Silicon

Blanton

Wang

Xue

et al. 2013

2013 IEEE/ACM International Conference on Computer-Aided Design (ICCAD)

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DREAMS (DFM Rule EvAluation using Manufactured Silicon) is a comprehensive methodology for evaluating the yield-preserving capabilities of a set of DFM (design for manufacturability) rules using the results of logic diagnosis performed on failed ICs. DREAMS is an improvement over prior art in that the distribution of rule violations over the diagnosis candidates and the entire design are taken into account along with the nature of the failure (e.g., bridge versus open) to appropriately weight the rules. Silicon and simulation results demonstrate the efficacy of the DREAMS methodology. Specifically, virtual data is used to demonstrate that the DFM rule most responsible for failure can be reliably identified even in light of the ambiguity inherent to a nonideal diagnostic resolution, and a corresponding rule-violation distribution that is counter-intuitive. We also show that the combination of physically-aware diagnosis and the nature of the violated DFM rule can be used together to improve rule evaluation even further. Application of DREAMS to the diagnostic results from an in-production chip provides valuable insight in how specific DFM rules improve yield (or not) for a given design manufactured in particular facility. Finally, we also demonstrate that a significant artifact of DREAMS is a dramatic improvement in diagnostic resolution. This means that in addition to identifying the most ineffective DFM rule(s), validation of that outcome via physical failure analysis of failed chips can be eased due to the corresponding improvement in diagnostic resolution.

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Section: Rule-violation Typesmentioning

confidence: 99%

DREAMS: DFM Rule EvAluation using Manufactured Silicon

Blanton

Wang

Xue

et al. 2013

2013 IEEE/ACM International Conference on Computer-Aided Design (ICCAD)

Self Cite

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“…One important step of fault diagnosis is to generate a suitable set of patterns that can be applied to the chips via automatic test equipment (ATE) such that proper diagnosis information of the chips can be collected and analyzed. Figure 1(a) shows a typical volume diagnosis flow [2][3][4][5][6][7][8][9][10]. A set of test patterns (TP) generated by an ATPG tool is applied to the chips via automatic test equipment (ATE) to produce a failure log (FL), i.e., the output responses of failing patterns.…”

Section: Introductionmentioning

confidence: 99%

“…The FL is then analyzed by a diagnosis analysis tool to derive a list of candidates (CD) for the PFA process. To reduce the number of fault candidates and increase the hit ratio of PFA, various techniques have been employed in the diagnosis analysis tool, including POIROT [2], single location at-a-time (SLAT) [3], diagnosis-assisted adaptive test (DAT) [4], machine-learning based methods [5][6], layout-aware diagnosis tools [7][8], design-partition analysis [9] and fault-rescoring tool [10]. Since only the original test pattern set is used in this flow, no extra patterns are needed.…”

Section: Introductionmentioning

confidence: 99%

An efficient diagnosis method to deal with multiple fault-pairs simultaneously using a single circuit model

Lee

Lien

2014

2014 IEEE 32nd VLSI Test Symposium (VTS)

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This paper proposes an efficient diagnosis-aware ATPG method that can quickly identify equivalent-fault pairs and generate diagnosis patterns for nonequivalent-fault pairs, where an (non)equivalent-fault pair contains two stuck-at faults that are (not) equivalent. A novel fault injection method is developed which allows one to embed all fault pairs undistinguished by the conventional test patterns into a circuit model with only one copy of the original circuit. Each pair of faults to be processed is transformed to a stuck-at fault and all fault pairs can be dealt with by invoking an ordinary ATPG tool for stuck-at faults just once. High efficiency of diagnosis pattern generation can be achieved due to 1) the circuit to be processed is read only once, 2) the data structure for ATPG process is constructed only once, 3) multiple fault pairs can be processed at a time, and 4) only one copy of the original circuit is needed. Experimental results show that this is the first reported work that can achieve 100% diagnosis resolutions for all ISCAS'89 and IWLS'05 benchmark circuits using an ordinary ATPG tool. Furthermore, we also find that the total number of patterns required to deal with all fault pairs in our method is smaller than that of the current state-of-the-art work.

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“…One important step of fault diagnosis is to generate a suitable set of patterns that can be applied to the chips via automatic test equipment (ATE) such that proper diagnosis information of the chips can be collected and analyzed. Figure 1(a) shows a typical volume diagnosis flow [2][3][4][5][6][7][8][9][10]. A set of test patterns (TP) generated by an ATPG tool is applied to the chips via an automatic test equipment (ATE) to produce a failure log (FL), i.e., the output responses of failing patterns.…”

Section: Introductionmentioning

confidence: 99%

“…The FL is then analyzed by a diagnosis analysis tool to derive a list of candidates (CD) for the PFA process. To reduce the number of fault candidates and increase the hit ratio of PFA, various techniques have been employed in the diagnosis analysis tool [2][3][4][5][6][7][8][9][10]. However, since only the original test pattern set is used in this flow, it is often inadequate to filter out some incorrect candidates.…”

Section: Introductionmentioning

confidence: 99%

An Efficient Diagnosis Pattern Generation Procedure to Distinguish Stuck-at Faults and Bridging Faults

Lee

2014

2014 IEEE 23rd Asian Test Symposium

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Fault Diagnosis is a critical process to identify the locations of physical defects in advanced integrated circuits. Current diagnosis tools often report multiple types of faults as defect candidates. Thus an efficient method to distinguish different types of faults is highly desired. Stuck-at and bridging faults are two most commonly used DC fault models during diagnosis. In this paper we present an efficient diagnosis pattern generation procedure to distinguish stuck-at faults and bridging faults. Two major techniques are proposed. The first one is a fault-inactivation methodFIM) that can quickly distinguish most fault pairs by inactivating one fault while detecting the other in each fault pair. The second one is a fault-types-transformation method (FTTM) that can transform the problem of distinguishing a stuck-at fault and a bridging fault into the problem of detecting a stuck-at fault. Both methods involve only one copy of the original circuit and require only an ordinary ATPG tool for stuck-at faults. Furthermore, both methods can deal with multiple fault pairs at a time and thus not only is the required CPU time small but also the dynamic test compaction capability of the ATPG tool can be utilized. Experiments on a large number of randomly selected fault pairs in ISCAS'89 and IWLS'05 benchmark circuits have been carried out. The results show that the FIM can distinguish about 91.9% of distinguishable fault pairs quickly and the FTTM can distinguish all other distinguishable fault pairs and identify all equivalent fault pairs. The average ratio of the number of diagnosis patterns over that of the test patterns for stuck-at faults is only 0.64. On average, one diagnosis pattern can distinguish 10.89 fault pairs.

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Physically-Aware Analysis of Systematic Defects in Integrated Circuits

Cited by 12 publications

References 95 publications

DREAMS: DFM Rule EvAluation using Manufactured Silicon

DREAMS: DFM Rule EvAluation using Manufactured Silicon

An efficient diagnosis method to deal with multiple fault-pairs simultaneously using a single circuit model

An Efficient Diagnosis Pattern Generation Procedure to Distinguish Stuck-at Faults and Bridging Faults

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