Models and Algorithmic Limits for an ECC-Based Approach to Hardening Sub-100-nm SRAMs

Author

Bajura, Michael A. ; Boulghassoul, Younes ; Naseer, Riaz ; DasGupta, Sandeepan ; Witulski, Arthur F. ; Sondeen, Jeff ; Stansberry, Scott D. ; Draper, Jeffrey ; Massengill, Lloyd W. ; Damoulakis, John N.

Author_Institution

Southern California Viterbi Univ., Marina Del Rey

Volume

54

Issue

4

fYear

2007

Firstpage

935

Lastpage

945

Abstract

A mathematical bit error rate (BER) model for upsets in memories protected by error-correcting codes (ECCs) and scrubbing is derived. This model is compared with expected upset rates for sub-100-nm SRAM memories in space environments. Because sub-100-nm SRAM memory cells can be upset by a critical charge (Q_crit) of 1.1 fC or less, they may exhibit significantly higher upset rates than those reported in earlier technologies. Because of this, single-bit-correcting ECCs may become impractical due to memory scrubbing rate limitations. The overhead needed for protecting memories with a triple-bit-correcting ECC is examined relative to an approximate 2X ldquoprocess generationrdquo scaling penalty in area, speed, and power.

Keywords

SRAM chips; error correction codes; error statistics; radiation effects; SRAM memory cells; bit error rate model; memory fault tolerance; memory scrubbing rate; radiation effects; single-bit-correcting error-correcting codes; triple-bit-correcting error-correcting codes; Bit error rate; CMOS technology; Circuits; Error correction codes; Government; Mathematical model; Power generation; Protection; Random access memory; Space technology; Error correction coding; memory fault tolerance; radiation effects;

fLanguage

English

Journal_Title

Nuclear Science, IEEE Transactions on

Publisher

ieee

ISSN

0018-9499

Type

jour

DOI

10.1109/TNS.2007.892119

Filename

4291685