Modelling and Test Generation for Crosstalk Faults in DSM Chips

In the era of deep submicron technology (DSM), many System-on-Chip (SoC) applications require the components to be operating at high clock speeds. With the shrinking feature size and ever increasing clock frequencies, the DSM technology has led to a well-known problem of Signal Integrity (SI) more especially in the connecting layout design. The increasing aspect ratios of metal wires and also the ratio of coupling capacitance over substrate capacitance result in electrical coupling of interconnects which leads to crosstalk problems. In this thesis, first the work carried out to model the crosstalk behaviour between aggressor and victim by considering the distributed RLGC parameters of interconnect and the coupling capacitance and mutual conductance between the two nets is presented. The proposed model also considers the RC linear models of the CMOS drivers and receivers. The behaviour of crosstalk in case of under etching problem has been studied and modelled by distributing and approximating the defect behaviour throughout the nets. Next, the proposed model has also been extended to model the behaviour of crosstalk in case of one victim is influenced by several aggressors by considering all aggressors have similar effect (worst-case) on victim. In all the above cases simulation experiments were also carried out and compared with well-known circuit simulation tool PSPICE. It has been proved that the generated crosstalk model is faster and the results generated are within 10% of error margin compared to latter simulation tool. Because of the accuracy and speed of the proposed model, the model is very useful for both SoC designers and test engineers to analyse the crosstalk behaviour. Each manufactured device needs to be tested thoroughly to ensure the functionality before its delivery. The test pattern generation for crosstalk faults is also necessary to test the corresponding crosstalk faults. In this thesis, the well-known PODEM algorithm for stuck-at faults is extended to generate the test patterns for crosstalk faults between single aggressor and single victim. To apply modified PODEM for crosstalk faults, the transition behaviour has been divided into two logic parts as before transition and after transition. After finding individually required test patterns for before transition and after transition, the generated logic vectors are appended to create transition test patterns for crosstalk faults. The developed algorithm is also applied for a few ISCAS 85 benchmark circuits and the fault coverage is found excellent in most circuits. With the incorporation of proposed algorithm into the ATPG tools, the efficiency of testing will be improved by generating the test patterns for crosstalk faults besides for the conventional stuck-at faults. In generating test patterns for crosstalk faults on single victim due to multiple aggressors, the modified PODEM algorithm is found to be more time consuming. The search capability of Genetic Algorithms in finding the required combination of several input factors for any optimized problem fascinated to apply GA for generating test patterns as generating the test pattern is also similar to finding the required vector out of several input transitions. Initially the GA is applied for generating test patterns for stuck-at faults and compared the results with PODEM algorithm. As the fault coverage is almost similar to the deterministic algorithm PODEM, the GA developed for stuck-at faults is extended to find test patterns for crosstalk faults between single aggressor and single victim. The elitist GA is also applied for a few ISCAS 85 benchmark circuits. Later the algorithm is extended to generate test patterns for worst-case crosstalk faults. It has been proved that elitist GA developed in this thesis is also very useful in generating test patterns for crosstalk faults especially for multiple aggressor and single victim crosstalk faults

Fault simulation and test generation for small delay faults

Delay faults are an increasingly important test challenge. Traditional delay fault models are incomplete in that they model only a subset of delay defect behaviors. To solve this problem, a more realistic delay fault model has been developed which models delay faults caused by the combination of spot defects and parametric process variation. According to the new model, a realistic delay fault coverage metric has been developed. Traditional path delay fault coverage metrics result in unrealistically low fault coverage, and the real test quality is not reflected. The new metric uses a statistical approach and the simulation based fault coverage is consistent with silicon data. Fast simulation algorithms are also included in this dissertation. The new metric suggests that testing the K longest paths per gate (KLPG) has high detection probability for small delay faults under process variation. In this dissertation, a novel automatic test pattern generation (ATPG) methodology to find the K longest testable paths through each gate for both combinational and sequential circuits is presented. Many techniques are used to reduce search space and CPU time significantly. Experimental results show that this methodology is efficient and able to handle circuits with an exponential number of paths, such as ISCAS85 benchmark circuit c6288. The ATPG methodology has been implemented on industrial designs. Speed binning has been done on many devices and silicon data has shown significant benefit of the KLPG test, compared to several traditional delay test approaches

Design-for-delay-testability techniques for high-speed digital circuits

The importance of delay faults is enhanced by the ever increasing clock rates and decreasing geometry sizes of nowadays' circuits. This thesis focuses on the development of Design-for-Delay-Testability (DfDT) techniques for high-speed circuits and embedded cores. The rising costs of IC testing and in particular the costs of Automatic Test Equipment are major concerns for the semiconductor industry. To reverse the trend of rising testing costs, DfDT is\ud getting more and more important

Modeling defective part level due to static and dynamic defects based upon site observation and excitation balance

Manufacture testing of digital integrated circuits is essential for high quality. However, exhaustive testing is impractical, and only a small subset of all possible test patterns (or test pattern pairs) may be applied. Thus, it is crucial to choose a subset that detects a high percentage of the defective parts and produces a low defective part level. Historically, test pattern generation has often been seen as a deterministic endeavor. Test sets are generated to deterministically ensure that a large percentage of the targeted faults are detected. However, many real defects do not behave like these faults, and a test set that detects them all may still miss many defects. Unfortunately, modeling all possible defects as faults is impractical. Thus, it is important to fortuitously detect unmodeled defects using high quality test sets. To maximize fortuitous detection, we do not assume a high correlation between faults and actual defects. Instead, we look at the common requirements for all defect detection. We deterministically maximize the observations of the leastobserved sites while randomly exciting the defects that may be present. The resulting decrease in defective part level is estimated using the MPGD model. This dissertation describes the MPGD defective part level model and shows how it can be used to predict defective part levels resulting from static defect detection. Unlike many other predictors, its predictions are a function of site observations, not fault coverage, and thus it is generally more accurate at high fault coverages. Furthermore, its components model the physical realities of site observation and defect excitation, and thus it can be used to give insight into better test generation strategies. Next, we investigate the effect of additional constraints on the fortuitous detection of defects-specifically, as we focus on detecting dynamic defects instead of static ones. We show that the quality of the randomness of excitation becomes increasingly important as defect complexity increases. We introduce a new metric, called excitation balance, to estimate the quality of the excitation, and we show how excitation balance relates to the constant τ in the MPGD model

Towards an embedded board-level tester: study of a configurable test processor

The demand for electronic systems with more features, higher performance, and less power consumption increases continuously. This is a real challenge for design and test engineers because they have to deal with electronic systems with ever-increasing complexity maintaining production and test costs low and meeting critical time to market deadlines. For a test engineer working at the board-level, this means that manufacturing defects must be detected as soon as possible and at a low cost. However, the use of classical test techniques for testing modern printed circuit boards is not sufficient, and in the worst case these techniques cannot be used at all. This is mainly due to modern packaging technologies, a high device density, and high operation frequencies of modern printed circuit boards. This leads to very long test times, low fault coverage, and high test costs. This dissertation addresses these issues and proposes an FPGA-based test approach for printed circuit boards. The concept is based on a configurable test processor that is temporarily implemented in the on-board FPGA and provides the corresponding mechanisms to communicate to external test equipment and co-processors implemented in the FPGA. This embedded test approach provides the flexibility to implement test functions either in the external test equipment or in the FPGA. In this manner, tests are executed at-speed increasing the fault coverage, test times are reduced, and the test system can be adapted automatically to the properties of the FPGA and devices located on the board. An essential part of the FPGA-based test approach deals with the development of a test processor. In this dissertation the required properties of the processor are discussed, and it is shown that the adaptation to the specific test scenario plays a very important role for the optimization. For this purpose, the test processor is equipped with configuration parameters at the instruction set architecture and microarchitecture level. Additionally, an automatic generation process for the test system and for the computation of some of the processor’s configuration parameters is proposed. The automatic generation process uses as input a model known as the device under test model (DUT-M). In order to evaluate the entire FPGA-based test approach and the viability of a processor for testing printed circuit boards, the developed test system is used to test interconnections to two different devices: a static random memory (SRAM) and a liquid crystal display (LCD). Experiments were conducted in order to determine the resource utilization of the processor and FPGA-based test system and to measure test time when different test functions are implemented in the external test equipment or the FPGA. It has been shown that the introduced approach is suitable to test printed circuit boards and that the test processor represents a realistic alternative for testing at board-level.Der Bedarf an elektronischen Systemen mit zusätzlichen Merkmalen, höherer Leistung und geringerem Energieverbrauch nimmt ständig zu. Dies stellt eine erhebliche Herausforderung für Entwicklungs- und Testingenieure dar, weil sie sich mit elektronischen Systemen mit einer steigenden Komplexität zu befassen haben. Außerdem müssen die Herstellungs- und Testkosten gering bleiben und die Produkteinführungsfristen so kurz wie möglich gehalten werden. Daraus folgt, dass ein Testingenieur, der auf Leiterplatten-Ebene arbeitet, die Herstellungsfehler so früh wie möglich entdecken und dabei möglichst niedrige Kosten verursachen soll. Allerdings sind die klassischen Testmethoden nicht in der Lage, die Anforderungen von modernen Leiterplatten zu erfüllen und im schlimmsten Fall können diese Testmethoden überhaupt nicht verwendet werden. Dies liegt vor allem an modernen Gehäuse-Technologien, der hohen Bauteildichte und den hohen Arbeitsfrequenzen von modernen Leiterplatten. Das führt zu sehr langen Testzeiten, geringer Testabdeckung und hohen Testkosten. Die Dissertation greift diese Problematik auf und liefert einen FPGA-basierten Testansatz für Leiterplatten. Das Konzept beruht auf einem konfigurierbaren Testprozessor, welcher im On-Board-FPGA temporär implementiert wird und die entsprechenden Mechanismen für die Kommunikation mit der externen Testeinrichtung und Co-Prozessoren im FPGA bereitstellt. Dadurch ist es möglich Testfunktionen flexibel entweder auf der externen Testeinrichtung oder auf dem FPGA zu implementieren. Auf diese Weise werden Tests at-speed ausgeführt, um die Testabdeckung zu erhöhen. Außerdem wird die Testzeit verkürzt und das Testsystem automatisch an die Eigenschaften des FPGAs und anderer Bauteile auf der Leiterplatte angepasst. Ein wesentlicher Teil des FPGA-basierten Testansatzes umfasst die Entwicklung eines Testprozessors. In dieser Dissertation wird über die benötigten Eigenschaften des Prozessors diskutiert und es wird gezeigt, dass die Anpassung des Prozessors an den spezifischen Testfall von großer Bedeutung für die Optimierung ist. Zu diesem Zweck wird der Prozessor mit Konfigurationsparametern auf der Befehlssatzarchitektur-Ebene und Mikroarchitektur-Ebene ausgerüstet. Außerdem wird ein automatischer Generierungsprozess für die Realisierung des Testsystems und für die Berechnung einer Untergruppe von Konfigurationsparametern des Prozessors vorgestellt. Der automatische Generierungsprozess benutzt als Eingangsinformation ein Modell des Prüflings (device under test model, DUT-M). Das entwickelte Testsystem wurde zum Testen von Leiterplatten für Verbindungen zwischen dem FPGA und zwei Bauteilen verwendet, um den FPGA-basierten Testansatz und die Durchführbarkeit des Testprozessors für das Testen auf Leiterplatte-Ebene zu evaluieren. Die zwei Bauteile sind ein Speicher mit direktem Zugriff (static random-access memory, SRAM) und eine Flüssigkristallanzeige (liquid crystal display, LCD). Die Experimente wurden durchgeführt, um den Ressourcenverbrauch des Prozessors und Testsystems festzustellen und um die Testzeit zu messen. Dies geschah durch die Implementierung von unterschiedlichen Testfunktionen auf der externen Testeinrichtung und dem FPGA. Dadurch konnte gezeigt werden, dass der FPGA-basierte Ansatz für das Testen von Leiterplatten geeignet ist und dass der Testprozessor eine realistische Alternative für das Testen auf Leiterplatten-Ebene ist

Topical Workshop on Electronics for Particle Physics

The purpose of the workshop was to present results and original concepts for electronics research and development relevant to particle physics experiments as well as accelerator and beam instrumentation at future facilities; to review the status of electronics for the LHC experiments; to identify and encourage common efforts for the development of electronics; and to promote information exchange and collaboration in the relevant engineering and physics communities