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Analysis and Optimization for Testing Using IEEE P1687Ghani Zadegan, Farrokh January 2010 (has links)
The IEEE P1687 (IJTAG) standard proposal aims at providing a standardized interface between on-chip embedded test, debug and monitoring logic (instruments), such as scan-chains and temperature sensors, and the Test Access Port of IEEE Standard 1149.1 mainly used for board test. A key feature in P1687 is to include Segment Insertion Bits (SIBs) in the scan path. SIBs make it possible to construct a multitude of different P1687 networks for the same set of instruments, and provide flexibility in test scheduling. The work presented in this thesis consists of two parts. In the first part, analysis regarding test application time is given for P1687 networks while making use of two test schedule types, namely concurrent and sequential test scheduling. Furthermore, formulas and novel algorithms are presented to compute the test time for a given P1687 network and a given schedule type. The algorithms are implemented and employed in extensive experiments on realistic industrial designs. In the second part, design of IEEE P1687 networks is studied. Designing the P1687 network that results in the least test application time for a given set of instruments, is a time-consuming task in the absence of automatic design tools. In this thesis work, novel algorithms are presented for automated design of P1687 networks which are optimized with respect to test application time and the required number of SIBs. The algorithms are implemented and demonstrated in experiments on industrial SOCs.
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Test Scheduling with Power and Resource Constraints for IEEE P1687Asani, Golnaz January 2012 (has links)
IEEE P1687 (IJTAG) is proposed to add more exibility|compared with IEEE 1149.1 JTAG|for accessing on-chip embedded test features called instruments. This exibility makes it possible to include and exclude instruments from the scan path. To reach a minimal test time, all instruments should be accessed concurrently. However, constraints such as power and resource constraints might limit concurrency. There is a need to consider power and resource constraints while developing the test schedule. This thesis consists of two parts. In the rst part, three test time calculation approaches, namely session-based test schedule with a xed scan path, session-based test schedule with a recongurable scan path, and session-less test schedule with a recongurable scan path are proposed. In the second part, three test scheduling approaches, namely session-based test scheduling, optimized session-based test scheduling, and optimized session-less test scheduling are studied and three algorithms are presented for each of the test scheduling approaches. Experiments are carried out using the test scheduling approaches and the results show that optimized sessionless test scheduling can signicantly reduce the test time compared with session-based test scheduling.
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