Genetic algorithm as self-test path and circular self-test path design method

The paper presents the use of Genetic Algorithm to search for non-linear Autonomous Test Structures (ATS) in Built-In Testing approach. Such structures can include essentially STP and CSTP and their modifications. Non-linear structures are more difficult to analyze than the widely used structures such as independent Test Pattern Generator and the Test Response Compactor realized by Linear Feedback Shift Registers. To reduce time-consuming test simulation of sequential circuit, it was used an approach based on the stochastic model of pseudo-random testing. The use of stochastic model significantly affects the time effectiveness of the search for evolutionary autonomous structures. In test simulation procedure, the block of sequential circuit memory is not disconnected. This approach does not require a special selection of memory registers such as BILBOs. A series of studies to test circuits set ISCAS’89 are made. The results of the study are very promising

New techniques for functional testing of microprocessor based systems

Electronic devices may be affected by failures, for example due to physical defects. These defects may be introduced during the manufacturing process, as well as during the normal operating life of the device due to aging. How to detect all these defects is not a trivial task, especially in complex systems such as processor cores. Nevertheless, safety-critical applications do not tolerate failures, this is the reason why testing such devices is needed so to guarantee a correct behavior at any time. Moreover, testing is a key parameter for assessing the quality of a manufactured product. Consolidated testing techniques are based on special Design for Testability (DfT) features added in the original design to facilitate test effectiveness. Design, integration, and usage of the available DfT for testing purposes are fully supported by commercial EDA tools, hence approaches based on DfT are the standard solutions adopted by silicon vendors for testing their devices. Tests exploiting the available DfT such as scan-chains manipulate the internal state of the system, differently to the normal functional mode, passing through unreachable configurations. Alternative solutions that do not violate such functional mode are defined as functional tests. In microprocessor based systems, functional testing techniques include software-based self-test (SBST), i.e., a piece of software (referred to as test program) which is uploaded in the system available memory and executed, with the purpose of exciting a specific part of the system and observing the effects of possible defects affecting it. SBST has been widely-studies by the research community for years, but its adoption by the industry is quite recent. My research activities have been mainly focused on the industrial perspective of SBST. The problem of providing an effective development flow and guidelines for integrating SBST in the available operating systems have been tackled and results have been provided on microprocessor based systems for the automotive domain. Remarkably, new algorithms have been also introduced with respect to state-of-the-art approaches, which can be systematically implemented to enrich SBST suites of test programs for modern microprocessor based systems. The proposed development flow and algorithms are being currently employed in real electronic control units for automotive products. Moreover, a special hardware infrastructure purposely embedded in modern devices for interconnecting the numerous on-board instruments has been interest of my research as well. This solution is known as reconfigurable scan networks (RSNs) and its practical adoption is growing fast as new standards have been created. Test and diagnosis methodologies have been proposed targeting specific RSN features, aimed at checking whether the reconfigurability of such networks has not been corrupted by defects and, in this case, at identifying the defective elements of the network. The contribution of my work in this field has also been included in the first suite of public-domain benchmark networks

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

Метод синтеза формирователя тестовой последовательности с перестраиваемыми параметрами, основанный на представлении логических функций в обобщенной форме

Предложен метод синтеза формирователя тестовых сигналов с перестраиваемыми временными параметрами тестового контента в зависимости от необходимости изменения глубины контроля в процессе оценки технического состояния синтезируемого цифрового автомат

Fault Detection Methodology for Caches in Reliable Modern VLSI Microprocessors based on Instruction Set Architectures

Η παρούσα διδακτορική διατριβή εισάγει μία χαμηλού κόστους μεθοδολογία για την ανίχνευση ελαττωμάτων σε μικρές ενσωματωμένες κρυφές μνήμες που βασίζεται σε σύγχρονες Αρχιτεκτονικές Συνόλου Εντολών και εφαρμόζεται με λογισμικό αυτοδοκιμής. Η προτεινόμενη μεθοδολογία εφαρμόζει αλγορίθμους March μέσω λογισμικού για την ανίχνευση τόσο ελαττωμάτων αποθήκευσης όταν εφαρμόζεται σε κρυφές μνήμες που περιέχουν μόνο στατικές μνήμες τυχαίας προσπέλασης όπως για παράδειγμα κρυφές μνήμες επιπέδου 1, όσο και ελαττωμάτων σύγκρισης όταν εφαρμόζεται σε κρυφές μνήμες που περιέχουν εκτός από SRAM μνήμες και μνήμες διευθυνσιοδοτούμενες μέσω περιεχομένου, όπως για παράδειγμα πλήρως συσχετιστικές κρυφές μνήμες αναζήτησης μετάφρασης. Η προτεινόμενη μεθοδολογία εφαρμόζεται και στις τρεις οργανώσεις συσχετιστικότητας κρυφής μνήμης και είναι ανεξάρτητη της πολιτικής εγγραφής στο επόμενο επίπεδο της ιεραρχίας. Η μεθοδολογία αξιοποιεί υπάρχοντες ισχυρούς μηχανισμούς των μοντέρνων ISAs χρησιμοποιώντας ειδικές εντολές, που ονομάζονται στην παρούσα διατριβή Εντολές Άμεσης Προσπέλασης Κρυφής Μνήμης (Direct Cache Access Instructions - DCAs). Επιπλέον, η προτεινόμενη μεθοδολογία εκμεταλλεύεται τους έμφυτους μηχανισμούς καταγραφής απόδοσης και τους μηχανισμούς χειρισμού παγίδων που είναι διαθέσιμοι στους σύγχρονους επεξεργαστές. Επιπρόσθετα, η προτεινόμενη μεθοδολογία εφαρμόζει την λειτουργία σύγκρισης των αλγορίθμων March όταν αυτή απαιτείται (για μνήμες CAM) και επαληθεύει το αποτέλεσμα του ελέγχου μέσω σύντομης απόκρισης, ώστε να είναι συμβατή με τις απαιτήσεις του ελέγχου εντός λειτουργίας. Τέλος, στη διατριβή προτείνεται μία βελτιστοποίηση της μεθοδολογίας για πολυνηματικές, πολυπύρηνες αρχιτεκτονικές.The present PhD thesis introduces a low cost fault detection methodology for small embedded cache memories that is based on modern Instruction Set Architectures and is applied with Software-Based Self-Test (SBST) routines. The proposed methodology applies March tests through software to detect both storage faults when applied to caches that comprise Static Random Access Memories (SRAM) only, e.g. L1 caches, and comparison faults when applied to caches that apart from SRAM memories comprise Content Addressable Memories (CAM) too, e.g. Translation Lookaside Buffers (TLBs). The proposed methodology can be applied to all three cache associativity organizations: direct mapped, set-associative and full-associative and it does not depend on the cache write policy. The methodology leverages existing powerful mechanisms of modern ISAs by utilizing instructions that we call in this PhD thesis Direct Cache Access (DCA) instructions. Moreover, our methodology exploits the native performance monitoring hardware and the trap handling mechanisms which are available in modern microprocessors. Moreover, the proposed Methodology applies March compare operations when needed (for CAM arrays) and verifies the test result with a compact response to comply with periodic on-line testing needs. Finally, a multithreaded optimization of the proposed methodology that targets multithreaded, multicore architectures is also presented in this thesi

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