These designs pose significant challenges towards the funnel management plan, flow, and tools. This paper introduces several test logic architectures that facilitate preemptive test scheduling for SC circuits with embedded deterministic test-based test data compression. This paper presents several techniques used to resolve problems surfacing when using scan bandwidth management to large industrial multicore system-on-nick (SC) designs with embedded test data compression. Exactly the same solutions allow efficient handling of physical constraints in realistic programs. Finally, condition-of-the-art SC test scheduling calculations are architected accordingly by looking into making provisions for: 1) establishing time-effective test designs 2) optimization of SC pin partitions 3) allocation of core-level channels according to scan data volume and 4) more flexible core-wise use of automatic test equipment funnel sources. An in depth situation study is highlighted herein with a number of experiments permitting someone to learn to compromise different architectures and test-related factors.

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V. Iyengar, A. Chandra, S. Schweizer, and K. Chakrabarty, “A unified approach for SC testing using test data compression and TAM optimization,” in Proc. Des., Autom. Test Eur. Conf. Exhibit. (DATE), 2003, pp. 1188–1189.

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