Predicting neutron induced soft error rates: Evaluation of accelerated ground based test methods

Author

Warren, Kevin M. ; Wilkinson, Jeffrey D. ; Weller, Robert A. ; Sierawski, Brian D. ; Reed, Robert A. ; Porter, Mark E. ; Mendenhall, Marcus H. ; Schrimpf, Ron D. ; Massengill, Lloyd W.

Author_Institution

Inst. for Space & Defense Electron., Vanderbilt Univ., Nashville, TN

fYear

2008

fDate

April 27 2008-May 1 2008

Firstpage

473

Lastpage

477

Abstract

In this work, heavy ion and energetic proton single event upset (SEU) cross sections are measured for a 4 Mbit CMOS, static random access memory (SRAM). Heavy ion upset cross sections were used to define a dosimetry model suitable for use in a Monte-Carlo, physics-based transport code, which is shown to be predictive for experimentally measured proton single event upset (SEU) cross sections. The simulator was used to quantify the difference between neutron and proton SEU cross sections and to evaluate the fidelity of currently established rate prediction methods. Simulations indicate that established test methods under-predict the FIT rate between 26- 35% for this technology.

Keywords

CMOS memory circuits; SRAM chips; integrated circuit testing; logic testing; neutron effects; proton effects; CMOS; Monte-Carlo analysis; accelerated ground based test method; dosimetry model; energetic proton single event upset; heavy ion effects; neutron induced soft error rates; physics-based transport code; rate prediction method; static random access memory; Energy measurement; Error analysis; Life estimation; Neutrons; Predictive models; Protons; Random access memory; SRAM chips; Single event upset; Testing;

fLanguage

English

Publisher

ieee

Conference_Titel

Reliability Physics Symposium, 2008. IRPS 2008. IEEE International

Conference_Location

Phoenix, AZ

Print_ISBN

978-1-4244-2049-0

Electronic_ISBN

978-1-4244-2050-6

Type

conf

DOI

10.1109/RELPHY.2008.4558931

Filename

4558931