Access Time Minimization in IEEE 1687 Networks

IEEE 1687 enables flexible access to the embedded (on-chip) instruments that are needed for post-silicon validation, debugging, wafer sort, package test, burn-in, printed circuit board bring-up, printed circuit board assembly manufacturing test, power-on self-test, and in-field test. At any of these scenarios, the instruments are accessed differently, and at a given scenario the instruments are accessed differently over time. It means the IEEE 1687 network needs to be frequently reconfigured from accessing one set of instruments to accessing a different set of instruments. Due to the need of frequent reconfiguration of the IEEE 1687 network it is important to (1) minimize the run-time for the algorithm finding the new reconfiguration, and (2) generate scan vectors with minimized access time. In this paper we model the reconfiguration problem using Boolean Satisfiability Problem (SAT). Compared to previous works we show significant reduction in run-time and we ensure minimal access time for the generated scan vectors

System-Level Access to On-Chip Instruments

Modern integrated circuits (ICs) contain thousands of instruments to enable testing, tuning, monitoring, and so on. These on-chip instruments must be accessed through the ICs’ life- time. However, when ICs are mounted on Printed Circuit Boards (PCBs), access from system-level is challenged due to complex system hierarchies with a multitude of interfaces. In this paper we enable access from system-level to chip-level instruments by proposing hardware, protocol, and communication schemes. We have validated our scheme by implementing a system with two ICs on a Field-Programmable Gate Array (FPGA) where each IC includes an IEEE Std. 1687 network, communication between ICs is with Serial Peripheral Interface (SPI) and communication with the outside is with Universal Asynchronous Receiver Transmitter (UART). In experiments we evaluate communication based on software (polling) and hardware (interrupt) as well as overhead in terms of transported data and needed area

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

Modellierung und automatische Generierung von FPGA-basierten Testinstrumenten für den strukturellen Leiterplattentest

Neue Bauformen von Schaltkreisen wie BGAs führen zu sinkenden Möglichkeiten des optischen und mechanischen Testzugriffs und stellen Testsysteme vor Probleme bei der Testbarkeit von Verbindungen zwischen ICs auf Leiterplatten. Damit verbunden sind eine reduzierte Testabdeckung und steigende Kosten. Besonders für FPGAs fehlen geeignete Methoden, bei denen sich das Testsystem automatisch den Gegebenheiten der zu testenden Leiterplatte anpasst. Diese Dissertation beschäftigt sich mit dem Problem des FPGA-basierten Testens. Das vorgestellte Konzept nutzt ausschließlich vorhandene Ressourcen des FPGAs, um Testalgorithmen in dessen Logik zu implementieren und erhöht die Herstellungskosten der Leiterplatte nicht. Die Ressourcen des FPGAs stehen während der Testphase exklusiv für das Testen zur Verfügung. Ausgehend vom Stand der Technik nicht-invasiver elektrischer Verfahren für Leiterplattentests werden aktuelle Ansätze und Methoden miteinander verglichen. Aus deren Stärken und Schwächen wird eine detaillierte Zielstellung für diese Dissertation erarbeitet. Es wird eine Methode zur Generierung von Testinstrumenten für das FPGA-basierte Testen vorgestellt, die die Ausführung von Testalgorithmen in den FPGA verlagern und eine vergleichbare oder bessere Testabdeckung sowie Testgeschwindigkeit als etablierte Verfahren liefert, ohne dafür auf manuelle Eingriffe bei der Generierung angewiesen zu sein. Im Rahmen eines Lösungsansatzes wird neben der Testsystemarchitektur eine Modellierung für die an den Verbindungstests beteiligten Schaltkreise vorgestellt. Hierbei wird die Ausführung der Testalgorithmen im FPGA entweder in Software auf einem softcore-basierten Prozessor oder direkt in Hardware als diskrete Logik in einem sogenannten Co-Prozessor ermöglicht. Mit der Methode ist es möglich jeden Schaltkreis getrennt und unabhängig von der Art seiner späteren Implementierung und den konkreten Gegebenheiten des Prüflings zu modellieren. Die Generierung aller nötigen Bestandteile in Software und Hardware, wie auch deren Integration zu einem Testinstrument erfolgen dabei vollständig automatisch. Kern der Arbeit ist die Modellierung und Generierung für eingebettete Testinstrumente, die auf der Testsystemarchitektur basieren. Der Fokus wird dabei auf die zeitlich korrekte Ansteuerung der an den Verbindungstests beteiligten Schaltkreise gelegt, ohne dabei eine konkrete Implementierung vorzugeben. In Untersuchungen wird die Generierung von Testinstrumenten für verschiedene Schaltkreise betrachtet. Die Ergebnisse belegen die Leistungsfähigkeit der vorgestellten Methode zur automatischen Generierung von FPGA-basierten Testinstrumenten und zeigen eine signifikante Beschleunigung des FPGA-basierten Verbindungstests.New types of cases for integrated circuits like BGAs are leading to a decreased optical and mechanical test access. They are causing problems for test systems when testing connections between integrated circuits on printed circuit boards. This causes decreasing test coverage and increasing test costs. Especially for FPGAs some appropriate methods that automatically adapt the test system to the conditions of the printed circuit board are missing. This thesis is about the problems of FPGA-based testing. The presented concept solely uses available resources of the FPGA to transfer test algorithms from external test equipment into the programmable logic of the FPGA and therefore does not increase the production costs of the printed circuit board. The resources of the FPGA are exclusively used for testing during the test phase. Based on state-of-the-art non-invasive electrical methods for printed circuit boards with FPGAs current approaches are compared and analyzed. From the strengths and weaknesses of the considered methods a detailed description of the goals that should be achieved with this thesis is discussed. A method for the generation of so called test instruments for FPGA-based testing is presented. This method transfers the execution of test algorithms into the FPGA and has a similar or better test coverage as well as test speed compared to the well-established techniques without the need for any manually actions when generating such systems. Besides the chosen test system architecture the modeling of integrated circuits that are part of the connection test is presented. The test system architecture allows the execution of test algorithms either in software on a soft-core processor or directly in dedicated logic, so called co-processors. With this method it is possible to model each integrated circuit independent of each other and also independent of the implementation in software or hardware. The generation of all software and hardware parts of the test system is done fully automatically. Central element of this thesis is the modeling and generation of embedded test instruments, based on the presented test system architecture. The focus is on the timing-correct control routines of the integrated circuits that are part of the connection test. All parts of the test system should be modeled independent of each other and without knowledge about the use case. In experiments the generation of test instruments for different integrated circuits is carried out. These experiments prove the performance of the proposed methods for automatic generation of FPGA-based test instrument and show a significant speed-up for FPGA-based tests of printed circuit boards

Reusing and Retargeting On-Chip Instrument Access Procedures in IEEE P1687

This paper discusses the reuse and retargeting of test instruments and test patterns using the IEEE P1687 standard in an era where reuse of existing functional elements and integration of IP blocks is accelerating rapidly. It briefly discusses the deficiencies of existing 1149.1 (JTAG) and 1500 standards and demonstrates how the new standard, P1687, plugs these exposures by specifying JTAG as an off-chip to on-chip interface to the instrument access infrastructure. It provides a simple example to underscore the need for the standard and then builds on this example to show how the standard can be used for more complex situations