Design for testing

About: Design for testing is a research topic. Over the lifetime, 3946 publications have been published within this topic receiving 63049 citations. The topic is also known as: Design for Testability, DFT.

A Designer’s Guide to Built-In Self-Test

Abstract: Preface. About the Author. 1. An Overview of BIST. 2. Fault Models, Detection, and Simulation. 3. Design for Testability. 4. Test Pattern Generation. 5. Output Response Analysis. 6. Manufacturing and System-Level Use of BIST. 7. Built-In Logic Block Observer. 8. Pseudo-Exhaustive BIST. 9. Circular BIST. 10. Scan-Based BIST. 11. Non-Intrusive BIST. 12. BIST for Regular Structures. 13. BIST for FPGAs and CPLDs. 14. Applying Digital BIST of Mixed-Signal Systems. 15. Merging BIST and Concurrent Fault Detection. Acronyms. Bibliography. Index.

High-level power modeling, estimation, and optimization

Abstract: Silicon area, performance, and testability have been, so far, the major design constraints to be met during the development of digital very-large-scale-integration (VLSI) systems. In recent years, however, things have changed; increasingly, power has been given weight comparable to the other design parameters. This is primarily due to the remarkable success of personal computing devices and wireless communication systems, which demand high-speed computations with low power consumption. In addition, there exists a strong pressure for manufacturers of high-end products to keep power under control, due to the increased costs of packaging and cooling this type of device. Last, the need of ensuring high circuit reliability has turned out to be more stringent. The availability of tools for the automatic design of low-power VLSI systems has thus become necessary. More specifically, following a natural trend, the interests of the researchers have lately shifted to the investigation of power modeling, estimation, synthesis, and optimization techniques that account for power dissipation during the early stages of the design flow. This paper surveys representative contributions to this area that have appeared in the recent literature.

Secure Scan: A Design-for-Test Architecture for Crypto Chips

Abstract: Scan-based design for test (DFT) is a powerful testing scheme, but it can be used to retrieve the secrets stored in a crypto chip, thus compromising its security. On one hand, sacrificing the security for testability by using a traditional scan-based DFT restricts its use in privacy sensitive applications. On the other hand, sacrificing the testability for security by abandoning the scan-based DFT hurts the product quality. The security of a crypto chip comes from the small secret key stored in a few registers, and the testability of a crypto chip comes from the data path and control path implementing the crypto algorithm. Based on this key observation, the authors propose a novel scan DFT architecture called secure scan that maintains the high test quality of traditional scan DFT without compromising the security. They used a hardware implementation of the advanced encryption standard to show that the traditional scan DFT scheme can compromise the secret key. They then showed that by using secure-scan DFT, neither the secret key nor the testability of the AES implementation is compromised

Built in self repair for embedded high density SRAM

Abstract: As the density of embedded memory increases, manufacturing yields of integrated circuits can reach unacceptable limits. Normal memory testing operations require BIST to effectively deal with problems such as limited access and "at speed" testing. In this paper we describe a novel methodology that extends the BIST concept to diagnosis and repair utilizing redundant components. We describe an application using redundant columns and accompanying algorithms. It allows for the autonomous repair of defective circuitry without external stimulus (e.g. laser repair). The method has been implemented with negligible timing penalties and reasonable area overhead.

Scan chain design for test time reduction in core-based ICs

Abstract: The size of the test vector set forms a significant factor in the overall production costs of ICs, as it defines the test application time and the required pin memory size of the test equipment. Large core-based ICs often require a very large test vector set for a high test coverage. This paper deals with the design of scan chains as transport mechanism for test patterns from IC pins to embedded cores and vice versa. The number of pins available to accommodate scan test is given, as well as the number of scan test patterns and scannable flip flops of each core. We present and analyze three scan chain architectures for core-based ICs, which aim at a minimum test vector set size. We give experimental results of the three architectures for an industrial IC. Furthermore we analyze the test time consequences of reusing cores with fixed internal scan chains in multiple ICs with varying design parameters.