Farrokh Ghani Zadegan

Access Time Analysis for IEEE P1687

The IEEE P1687 (IJTAG) standard proposal aims at providing a standardized interface between the IEEE Standard 1149.1 test access port (TAP) and on-chip embedded test, debug and monitoring logic (instruments), such as scan chains and temperature sensors. A key feature in P1687 is to include Segment Insertion Bits (SIBs) in the scan path to allow flexibility both in designing the instrument access network and in scheduling the access to instruments. This paper presents algorithms to compute the overall access time (OAT) for a given P1687 network. The algorithms are based on analysis for flat and hierarchical network architectures, considering two access schedules, i.e., concurrent schedule and sequential schedule. In the analysis, two types of overhead are identified, i.e., network configuration data overhead and JTAG protocol overhead. The algorithms are implemented and employed in a parametric analysis and in experiments on realistic industrial designs.

Design automation for IEEE P1687

The IEEE P1687 (IJTAG) standard proposal aims at standardizing the access to embedded test and debug logic (instruments) via the JTAG TAP. P1687 specifies a component called Segment Insertion Bit (SIB) which makes it possible to construct a multitude of alternative P1687 instrument access networks for a given set of instruments. Finding the best access network with respect to instrument access time and the number of SIBs is a time-consuming task in the absence of EDA support. This paper is the first to describe a P1687 design automation tool which constructs and optimizes P1687 networks. Our EDA tool, called PACT, considers the concurrent and sequential access schedule types, and is demonstrated in experiments on industrial SOCs, reporting total access time and average access time.

Test Time Analysis for IEEE P1687

The IEEE P1687 (IJTAG) standard proposal aims at providing a standardized interface between on-chip embedded logic (instruments), such as scan-chains and temperature sensors, and the IEEE 1149.1 standard which provides test data transport and test protocol for board test. A key feature in P1687 is to include Select Instrument Bits (SIBs) in the scan path to allow flexibility in test architecture design and test scheduling. This paper presents algorithms to compute the test time in a P1687 context. The algorithms are based on analysis for flat and hierarchical test architectures, considering two test schedule types - concurrent and sequential test scheduling. Furthermore, two types of overhead are identified, i.e. control data overhead and JTAG protocol overhead. The algorithms are implemented and employed in experiments on realistic industrial designs.

Accessing Embedded DfT Instruments with IEEE P1687

While the advancement in semiconductor technologies enables manufacturing of highly advanced and complex integrated circuits, there is an increasing need of embedded (on-chip) instruments for test, debug, diagnosis, configuration, monitoring, etc. A key challenge is how to access these instruments from chip terminals in a low-cost, non-intrusive, standardized, flexible and scalable manner. The well-adopted IEEE 1149.1 (Joint Test Action Group (JTAG)) standard offers low-cost, non-intrusive and standardized access but lacks flexibility and scalability, which is addressed by the on-going IEEE P1687 (Internal JTAG (IJTAG)) standardization initiative. This paper discusses the need of embedded instrumentation, the shortcomings of IEEE 1149.1 as well as features and challenges of IEEE P1687.