Title :
Soft-programmable bypass switch design for defect-tolerant arrays
Author_Institution :
Dept. of Electr. & Comput. Eng., Carnegie Mellon Univ., Pittsburgh, PA, USA
Abstract :
Most wafer-scale processing arrays include bypass switches and wiring to permit signals to be routed around faulty modules. In some cases, the bypass circuitry contains registers to maintain data synchronization. The ideal switch design maximizes routing flexibility and switch yield while minimizing switch area and signal delay. Unfortunately these design goals work at cross-purposes. The goals also vary in importance, depending on the wafer architecture. For example, some architectures can cope with bypass logic failures, while others cannot. The ability to cope with failures may be a function of the failure mode. The author examines a number of bypass switch circuit and layout designs, and how well they meet to the design goals. He uses the DVLASIC distributed catastrophic fault yield simulator to perform yield computations
Keywords :
MOS integrated circuits; VLSI; cellular arrays; fault tolerant computing; integrated circuit technology; microprocessor chips; semiconductor switches; DVLASIC distributed catastrophic fault yield simulator; WSI; bypass logic failures; bypass switch circuit; bypass switches; data synchronization; defect-tolerant arrays; design goals; layout designs; minimizing switch area; routing flexibility; signal delay; switch yield; wafer architecture; wafer-scale processing arrays; yield computations; Circuit faults; Delay; Logic; Registers; Routing; Signal design; Signal processing; Switches; Switching circuits; Wiring;
Conference_Titel :
Wafer Scale Integration, 1990. Proceedings., [2nd] International Conference on
Conference_Location :
San Francisco, CA
Print_ISBN :
0-8186-9013-5
DOI :
10.1109/ICWSI.1990.63906
