Chih-Wea Wang

A built-in self-test and self-diagnosis scheme for embedded SRAM

Embedded memory test and diagnosis is becoming an important issue in system-on-chip (SOC) development. Direct access of the memory cores from the limited number of I/O pins is usually not feasible. Built-in self-diagnosis (BISD), which include built-in self-test (BIST), is rapidly becoming the most acceptable solution. We propose a BISD design and a fault diagnosis system for embedded SRAM. It supports manufacturing test as well as diagnosis for design verification and yield improvement. The proposed BISD circuit is on-line programmable for its March test algorithms. Test chips have been designed and implemented. Our experimental results show that the BISD hardware overhead is about 2.4% for a typical 128 Kb SRAM and only 0.65% for a 2 Mb SRAM.

RAMSES-FT: a fault simulator for flash memory testing and diagnostics

In this paper we present a fault simulator for flash memory testing and diagnostics, called RAMSES-FT. The fault simulator is designed for easy inclusion of new fault models by adding their fault descriptors without modifying the simulation engine. The flash memory fault models are discussed, based on the failures defined in the IEEE 1005 Standard. Both the NOR-type and NAND-type flash memory architectures are covered. Our flash memory fault simulator uses a parallel simulation strategy to reduce the simulation time complexity from O(N/sup 3/) to O(N/sup 2/), where N is the number of cells. With the proposed scaling method for March tests, the simulation time complexity is further reduced to O(W/sup 2/), where W is the word width of the memory. The fault simulator supports March algorithms as well as single memory operations, covering most of the flash memory tests. With RAMSES-FT we have developed a diagnostic algorithm that can distinguish the target flash memory faults.

A built-in self-test and self-diagnosis scheme for heterogeneous SRAM clusters

Testing and diagnosis are important issues in system-on-chip (SoC) development, as more and more embedded cores are being integrated into the chips. In this paper we propose a built-in self-test (BIST) and self-diagnosis (BISD) scheme for embedded SRAMs, suitable for SoC applications. It supports manufacturing test as well as diagnosis for design verification and yield improvement. With low hardware cost, our memory BISD approach can handle various types of SRAM, including pipelined, multi-port, and multi-clock architectures. In addition, a test scheduling methodology and a BISD compiler are also implemented, which reduce the testing time as well as test development time.

Test scheduling of BISTed memory cores for SoC

The test scheduling of memory cores can significantly affect the test time and power of system chips. We propose a test scheduling algorithm for BISTed memory cores to minimize the overall testing time under the test power constraint. The proposed algorithm combines several approaches for a near-optimal result, based on the properties of BISTed memory cores. By proper partitioning, an analytic exhaustive search finds optimal results for large memory cores, while a heuristic ordering with simulated annealing further handles a large amount of smaller memory cores. On the average, the results are within 1% difference of the optimal solution for the cases of 200 memory cores.

Simulation-based test algorithm generation and port scheduling for multi-port memories

The paper presents a simulation-based test algorithm generation and test scheduling methodology for multi-port memories. The purpose is to minimize the testing time while keeping the test algorithm in a simple and regular format for easy test generation, fault diagnosis, and built-in self-test (BIST) circuit implementation. Conventional functional fault models are used to generate tests covering most defects. In addition, multi-port specific defects are covered using structural fault models. Port-scheduling is introduced to take advantage of the inherent parallelism among different ports. Experimental results for commonly used multi-port memories, including dual-port, four-port, and

Fault pattern oriented defect diagnosis for memories

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Test scheduling and test access architecture optimization for system-on-chip

-read-1-write memories, have been obtained, showing that efficient test algorithms can be generated and scheduled to meet different test bandwidth constraints. Moreover, memories with more ports benefit more with respect to testing time.

A Built-in Self-Test Scheme with Diagnostics Support for Embedded SRAM

Failure analysis (FA) and diagnosis of memory cores plays a key role in system-on-chip (SOC) product development and yield ramp-up. Conventional FA based on bitmaps and the experiences of the FA engineer is time consuming and error prone. The increasing time-to-volume pressure on semiconductor products calls for new development flow that enables the product to reach a profitable yield level as soon as possible. Demand in methodologies that allow FA automation thus increases rapidly in recent years. This paper proposes a systematic diagnosis approach based on failure patterns and functional fault models of semiconductor memories. By circuit-level simulation and analysis, we have also developed a fault pattern generator. Defect diagnosis and FA can be performed automatically by using the fault patterns, reducing the time in yield improvement. The main contribution of the paper is thus a methodology and procedure for accelerating FA and yield optimization for semiconductor memories.

FAME: A Fault-Pattern Based Memory Failure Analysis Framework

We propose an efficient test scheduling and test access architecture for system-on-chip. The test time and test control complexity are optimized under the test power and test access mechanism (TAM) resource constraints. Using our heuristic algorithms, the test scheduling can be done rapidly with small test time penalty when compared with previous works. Under an existing SoC test framework, the test access hardware can be generated from the scheduling result. Experimental results show that the proposed scheduling is hardware efficient. The system integrator can evaluate the test access architecture and perform rest scheduling systematically.

Failure factor based yield enhancement for SRAM designs

In this paper we propose a novel built-in self-test (BIST) design for embedded SRAM cores. Our contribution includes a compact and efficient BIST circuit with diagnosis support and an automatic diagnostic system. The diagnosis module of our BIST circuit can capture the error syndromes as well as fault locations for the purposes of repair and fault/failure analysis. In addition, our design provides programmability for custom March algorithms with lower hardware cost. The combination of the on-line programming mode and diagnostic system dramatically reduces the effort in design debugging and yield enhancement. We have designed and implemented test chips with our BIST design. Experimental results show that the area overhead of the proposed BIST design is only 2.4% for a 128 KB SRAM, and 0.65% for a 2 MB one.