VLSI Testing and Test Power

This paper first reviews the basics of VLSI testing, focusing on test generation and design for testability. Then it discusses the impact of test power in scan testing, and highlights the need for low-power VLSI testing.2011 International Green Computing Conference and Workshops (IGCC 2011), July 25-28, 2011, Orlando, FL, US

CAT: A Critical-Area-Targeted Test Set Modification Scheme for Reducing Launch Switching Activity in At-Speed Scan Testing

Reducing excessive launch switching activity (LSA) is now mandatory in at-speed scan testing for avoiding test-induced yield loss, and test set modification is preferable for this purpose. However, previous low-LSA test set modification methods may be ineffective since they are not targeted at reducing launch switching activity in the areas around long sensitized paths, which are spatially and temporally critical for test-induced yield loss. This paper proposes a novel CAT (Critical-Area-Targeted) low-LSA test modification scheme, which uses long sensitized paths to guide launch-safety checking, test relaxation, and X-filling. As a result, launch switching activity is reduced in a pinpoint manner, which is more effective for avoiding test-induced yield loss. Experimental results on industrial circuits demonstrate the advantage of the CAT scheme for reducing launch switching activity in at-speed scan testing.2009 Asian Test Symposium, 23-26 November 2009, Taichung, Taiwa

A GA-Based Method for High-Quality X-Filling to Reduce Launch Switching Activity in At-speed Scan Testing

Power-aware X-filling is a preferable approach to avoiding IR-drop-induced yield loss in at-speed scan testing. However, the quality of previous X-filling methods for reducing launch switching activity may be unsatisfactory, due to low effect (insufficient and global-only reduction) and/or low scalability (long CPU time). This paper addresses this quality problem with a novel, GA (Genetic Algorithm) based X-filling method, called GA-fill. Its goals are (1) to achieve both effectiveness and scalability in a more balanced manner, and (2) to make the reduction effect of launch switching activity more concentrated on critical areas that have higher impact on IR-drop-induced yield loss. Evaluation experiments are being conducted on benchmark and industrial circuits, and initial results have demonstrated the usefulness of GA-fill.2009 15th IEEE Pacific Rim International Symposium on Dependable Computing, 16-18 November 2009, Shanghai, Chin

On Guaranteeing Capture Safety in At-Speed Scan Testing with Broadcast-Scan-Based Test Compression

Capture safety has become a major concern in at-speed scan testing since strong power supply noise caused by excessive launch switching activity (LSA) at transition launching in an at-speed test cycle often results in severe timing-failure-induced yield loss. Recently, a basic RM (rescue-&-mask) test generation scheme was proposed for guaranteeing capture safety rather than merely reducing LSA to some extent. This paper extends the basic RM scheme to broadcast-scan-based test compression by uniquely solving two test-compression-induced problems, namely (1) input X-bit insufficiency (i.e., fewer input X-bits are available for LSA reduction due to test compression) and (2) output X-bit impact (i.e., output X-bits may reduce fault coverage due to test response compaction). This leads to the broadcast-RM (broadcast-scan-based rescue-&-mask) test generation scheme. Evaluations on large benchmark circuits and an industrial circuit of about 1M gates clearly demonstrate that this novel scheme can indeed guarantee capture safety in at-speed scan testing with broadcast-scan-based test compression while minimizing its impact on both test quality and test costs.2013 26th International Conference on VLSI Design, 5-10 January 2013, Pune, Indi

DART: Dependable VLSI Test Architecture and Its Implementation

Although many electronic safety-related systems require very high reliability, it is becoming harder and harder to achieve it because of delay-related failures, which are caused by decreased noise margin. This paper describes a technology named DART and its implementation. The DART repeatedly measures the maximum delay of a circuit and the amount of degradation in field, in consequence, confirms the marginality of the circuit. The system employing the DART will be informed the significant reduction of delay margin in advance of a failure and be able to repair it at an appropriate time. The DART also equips a technique to improve the test coverage using the rotating test and a technique to consider the test environment such as temperature or voltage using novel ring-oscillator-based monitors. The authors applied the proposed technology to an industrial design and confirmed its effectiveness and availability with reasonable resources.2012 IEEE International Test Conference, 5-8 November 2012, Anaheim, CA, US

Logic/Clock-Path-Aware At-Speed Scan Test Generation for Avoiding False Capture Failures and Reducing Clock Stretch

IR-drop induced by launch switching activity (LSA) in capture mode during at-speed scan testing increases delay along not only logic paths (LPs) but also clock paths (Cps). Excessive extra delay along LPs compromises test yields due to false capture failures, while excessive extra delay along CPs compromises test quality due to test clock stretch. This paper is the first to mitigate the impact of LSA on both LPs and CPs with a novel LCPA (Logic/Clock Path-Aware) at-speed scan test generation scheme, featuring (1) a new metric for assessing the risk of false capture failures based on the amount of LSA around both LPs and CPs, (2) a procedure for avoiding false capture failures by reducing LSA around LPs or masking uncertain test responses, and (3) a procedure for reducing test clock stretch by reducing LSA around CPs. Experimental results demonstrate the effectiveness of the LCPA scheme in improving test yields and test quality.2015 IEEE 24th Asian Test Symposium (ATS), 22-25 November 2015, Mumbai, Indi

A Novel Scheme to Reduce Power Supply Noise for High-Quality At-Speed Scan Testing

High-quality at-speed scan testing, characterized by high small-delay-defect detecting capability, is indispensable to achieve high delay test quality for DSM circuits. However, such testing is susceptible to yield loss due to excessive power supply noise caused by high launch-induced switching activity. This paper addresses this serious problem with a novel and practical post-ATPG X-filling scheme, featuring (1) a test relaxation method, called path keeping X-identification, that finds don\u27t-care bits from a fully-specified transition delay test set while preserving its delay test quality by keeping the longest paths originally sensitized for fault detection, and (2) an X-filling method, called justification-probability-based fill (JP-fill), that is both effective and scalable for reducing launch-induced switching activity. This scheme can be easily implemented into any ATPG flow to effectively reduce power supply noise, without any impact on delay test quality, test data volume, area overhead, and circuit timing.2007 IEEE International Test Conference, 21-26 October 2007, Santa Clara, CA, US

On pinpoint capture power management in at-speed scan test generation

This paper proposes a novel scheme to manage capture power in a pinpoint manner for achieving guaranteed capture power safety, improved small-delay test capability, and minimal test cost impact in at-speed scan test generation. First, switching activity around each long path sensitized by a test vector is checked to characterize it as hot (with excessively-high switching activity), warm (with normal/functional switching activity), or cold (with excessively-low switching activity). Then, X-restoration/X-filling-based rescue is conducted on the test vector to reduce switching activity around hot paths. If the rescue is insufficient to turn a hot path into a warm path, mask is then conducted on expected test response data to instruct the tester to ignore the potentially-false test response value from the hot path, thus achieving guaranteed capture power safety. Finally, X-restoration/X-filling-based warm-up is conducted on the test vector to increase switching activity around cold paths for improving their small-delay test capability. This novel approach of pinpoint capture power management has significant advantages over the conventional approach of global capture power management, as demonstrated by evaluation results on large ITC\u2799 benchmark circuits and detailed path delay analysis.2012 IEEE International Test Conference, 5-8 November 2012, Anaheim, CA, US

High Quality Delay Testing Scheme for a Self-Timed Microprocessor

RÉSUMÉ La popularité d’internet et la quantité toujours croissante de données qui transitent à travers ses terminaux nécessite d’importantes infrastructures de serveurs qui consomment énormément d’énergie. Par conséquent, et puisqu’une augmentation de la consommation d’énergie se traduit par une augmentation des coûts, la demande pour des processeurs efficaces en énergie est en forte hausse. Une manière d’augmenter l’efficacité énergétique des processeurs consiste à moduler la fréquence d’opération du système en fonction de la charge de travail. Les processeurs endochrones et asynchrones sont une des solutions mettant en œuvre ce principe de modulation de l’activité à la demande. Cependant, les méthodes de conception non conventionnelles qui leur sont associées, en particulier en termes de testabilité et d’automation, sont un frein au développement de ce type de systèmes. Ce travail s’intéresse au développement d’une méthode de test de haute qualité adressée aux pannes de retards dans une architecture de processeur endochrone spécifique, appelée AnARM. La méthode proposée consiste à détecter les pannes à faibles retards (PFR) dans l’AnARM en tirant profit des lignes à délais configurables intégrées. Ces pannes sont connues pour passer au travers des modèles de pannes de retards utilisés habituellement (les pannes de retards de portes). Ce travail s’intéresse principalement aux PFR qui échappent à la détection des pannes de retards de portes mais qui sont suffisamment longues pour provoquer des erreurs dans des conditions normales d’opération. D’autre part, la détection de pannes à très faibles retards est évitée, autant que possible, afin de limiter le nombre de faux positifs. Pour réaliser un test de haute qualité, ce travail propose, dans un premier temps, une métrique de test dédiée aux PFR, qui est mieux adaptée aux circuits endochrones, puis, dans un second temps, une méthode de test des pannes de retards basée sur la modulation de la vitesse des lignes à délais intégrés, qui s’adapte à un jeu de vecteurs de test préexistant.Ce travail présente une métrique de test ciblant les PFR, appelée pourcentage de marges pondérées (PoMP), ainsi qu’un nouveau modèle de test pour les PFR (appelé test de PFR idéal).----------ABSTRACT The popularity of the Internet and the huge amount of data that is transfered between devices nowadays requires very powerful servers that demand lots of power. Since higher power consumptions mean more expenses to companies, there is an increase in demand for power eÿcient processors. One of the ways to increase the power eÿciency of processors is to adapt the processing speeds and chip activity according the needed computation load. Self-timed or asynchronous processors are one of the solutions that apply this principle of activity on demand. However, their unconventional design methodology introduces several challenges in terms of testability and design automation. This work focuses on developing a high quality delay test for a specific architecture of self-timed processors called the AnARM. The proposed delay test focuses on catching e˙ective small-delay defects (SDDs) in the AnARM by taking advantage of built-in configurable delay lines. Those defects are known to escape one of the most commonly used delay fault models (the transition delay fault model). This work mainly focuses on e˙ective SDDs which can escape transition delay fault testing and are large enough to fail the circuit under normal operating conditions. At the same time, catching very small delay defects is avoided, when possible, to avoid falsely failing functional chips. To build the high quality delay test, this work develops an SDD test quality metric that is better suited for circuits with adaptable speeds. Then, it builds a delay test optimizer that adapts the built-in delay lines speeds to a preexisting at-speed pattern set to create a high quality SDD test. This work presents a novel SDD test quality metric called the weighted slack percentage (WeSPer), along with a new SDD testing model (named the ideal SDD test model). WeSPer is built to be a flexible metric capable of adapting to the availability of information about the circuit under test and the test environment. Since the AnARM can use multiple test speeds, WeSPer computation takes special care of assessing the effects of test frequency changes on the test quality. Specifically, special care is taken into avoiding overtesting the circuit. Overtesting will cause circuits under test to fail due to defects that are too small to affect the functionality of these circuits in their present state. A computation framework is built to compute WeSPer and compare it with other existing metrics in the literature over a large sets of process-voltage-temperature computation points. Simulations are done on a selected set of known benchmark circuits synthesized in the 28nm FD-SOI technology from STMicroelectronics

An evaluation of the nature and role of the `glory of the Lord' in Ezekiel 1-24

This thesis evaluates the nature and role of `the glory of the Lord,' hwhy-dwbk, in Ezekiel 1-24. The introductory chapter will present the relevance of the topic as well as purview the scope of the thesis and the structure of its presentation. Chapter two lays an interpretive foundation for the glory pericope within a central theme in the book of Ezekiel. The intended impact on the exilic audience is discerned through examining the characteristic features of the hwhy-dwbk in Chapter 3. Chapter four identifies three functions of the hwhy-dwbk . A final function of the hwhy-dwbk is explored in its relationship to `the son of adam' in chapter five. A summary of the hypothesis is provided in chapter 6 along with a conclusion.Biblical and Ancient studiesM. A. (Old Testament