DocumentCode
3216816
Title
Comparing reliability predictions to field data for plastic parts in a military, airborne environment
Author
Brown, Laura M.
Author_Institution
Northrop Grumman Electron. Syst., Baltimore, MD, USA
fYear
2003
fDate
2003
Firstpage
207
Lastpage
213
Abstract
This paper examines two popular prediction methods and compares the results to field data collected on plastic encapsulated microcircuits (PEMs) operating in a military, airborne environment. The comparison study focused on three digital circuit card assemblies (CCAs) designed primarily with plastic, surface mount parts. Predictions were completed using MIL-HDBK-217 models and PRISW®, the latest software tool developed by the Reliability Analysis Center (RAC). The MIL-HDBK-217 predictions which correlated best to the field data were based on quality levels (πQ) of 2 and 3, rather than the typical πQ values of 5 or higher, traditionally assigned per the handbook´s screening classifications for commercial, plastic parts. The initial findings from the PRISM® tool revealed the predictions were optimistic in comparison to the observed field performance, meaning the predictions yielded higher mean time to failure (MTTF) values than demonstrated. Further evaluation of the PRISM® models showed how modifying default values could improve the prediction accuracy. The impact of the system level multiplier was also determined to be a major contributor to the difference between PRISM® predictions and field data. Finally, experience data proved valuable in refining the prediction results. The findings from this study provide justification to modify specific modeling factors to improve the predictions for PEMs, and also serve as a baseline to evaluate future alternative prediction methods.
Keywords
electronic engineering computing; encapsulation; integrated circuit reliability; military avionics; plastics; MIL-HDBK-217; MTTF; PRISM software tool; Reliability Analysis Center; digital circuit card assemblies; field data; mean time to failure; military airborne environment; plastic encapsulated microcircuit; plastic parts; reliability predictions; system level multiplier; Accuracy; Aerospace materials; Assembly systems; Costs; Digital circuits; Failure analysis; Plastic packaging; Prediction methods; Predictive models; Software tools;
fLanguage
English
Publisher
ieee
Conference_Titel
Reliability and Maintainability Symposium, 2003. Annual
ISSN
0149-144X
Print_ISBN
0-7803-7717-6
Type
conf
DOI
10.1109/RAMS.2003.1181927
Filename
1181927
Link To Document