Title :
Reducing DUE-FIT of caches by exploiting acoustic wave detectors for error recovery
Author :
Upasani, Gaurang ; Vera, Xavier ; Gonzalez, Adriana
Abstract :
Cosmic radiation induced soft errors have emerged as a key challenge in computer system design. The exponential increase in the transistor count will drive the per chip fault rate sky high. New techniques for detecting errors in the logic and memories that allow meeting the desired failures in-time (FIT) budget in future chip multiprocessors (CMPs) are essential. Among the two major contributors towards soft error rate, silent data corruption (SDC) and detected unrecoverable error (DUE), DUE is the largest. Moreover, processors can experience a super-linear increase in DUE when the size of the write-back cache is doubled. This paper targets the DUE problem in write-back data caches. We analyze the cost of protection against single bit and multi-bit upsets into caches. Our results show that the proposed mechanism can reduce the DUE to “0” with minimum area, power and performance overheads.
Keywords :
acoustic transducers; cache storage; failure analysis; fault tolerant computing; microprocessor chips; multiprocessing systems; performance evaluation; power aware computing; radiation hardening (electronics); CMP; SDC; acoustic wave detectors; cache DUE-FIT reduction; chip multiprocessors; computer system design; cosmic radiation induced soft errors; detected unrecoverable error; error detection; error recovery; failures in-time; multibit upsets; per chip fault rate; performance overheads; power overheads; silent data corruption; single bit upsets; soft error rate; write-back cache size; write-back data caches; Accuracy; Acoustic waves; Detectors; Equations; Estimation; Mathematical model; Program processors;
Conference_Titel :
On-Line Testing Symposium (IOLTS), 2013 IEEE 19th International
Conference_Location :
Chania
DOI :
10.1109/IOLTS.2013.6604056
