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{{multiple issues|deadend=February 2011|one source=February 2011|orphan=February 2011|refimprove=February 2011|wikify=February 2011}}
'''Reliability Prediction for Electronic Components'''
A prediction of [[reliability]] is an important element in the process of selecting equipment for use by [[telecommunications]] [[service providersprovider]]s and other buyers of [[electronic equipment]]. Reliability is a measure of the frequency of equipment failures as a function of time. Reliability has a major impact on maintenance and repair costs and on the continuity of service.<ref>Terry Donovan, Senior Systems Engineer Telcordia Technologies. Member of Optical Society of America, IEEE, "Automated Reliability Prediction, SR-332, Issue 3", January 2011; "Automated Reliability Prediction (ARPP), FD-ARPP-01, Issue 11", January 2011</ref>
Every product has a [[failure rate]], λ which is the number of units failing per unit time. This failure rate changes throughout the life of the product. It is the manufacturer’s aim to ensure that product in the “infant“[[infant mortality]] period” does not get to the customer. This leaves a product with a useful life period during which failures occur randomly i.e., λ is constant, and finally a wear-out period, usually beyond the products useful life, where λ is increasing.
 
=== Definition of Reliability ===
A practical definition of reliability is “the [[probability]] that a piece of equipment operating under specified conditions shall perform satisfactorily for a given period of time”. The reliability is a number between 0 and 1.
 
=== MTBF and MTTF ===
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Reliability predictions:
:* '''Help assess the effect of product reliability on the maintenance activity and on the quantity of spare units required for acceptable field performance of any particular system.''' For example, predictions of the frequency of unit level maintenance actions can be obtained. Reliability prediction can be used to size spare populations.
:* '''Provide necessary input to system-level reliability models.''' System-level reliability models can subsequently be used to predict, for example, frequency of system outages in [[Steady state (electronics)|steady-state]], frequency of system outages during early life, expected [[downtime]] per year, and system availability.
:* '''Provide necessary input to unit and system-level Life Cycle Cost Analyses.''' [[Life cycle cost analysis|Life cycle cost studies]] determine the cost of a product over its entire life. Therefore, how often a unit will have to be replaced needs to be known. Inputs to this process include unit and system failure rates. This includes how often units and systems fail during the first year of operation as well as in later years.
:* '''Assist in deciding which product to purchase from a list of competing products.''' As a result, it is essential that reliability predictions be based on a common procedure.
:* '''Can be used to set factory test standards for products requiring a reliability test.''' Reliability predictions help determine how often the system should fail.
:* '''Are needed as input to the analysis of complex systems such as switching systems and digital cross-connect systems.''' It is necessary to know how often different parts of the system are going to fail even for [[redundant]] components.
:* '''Can be used in design trade-off studies.''' For example, a supplier could look at a design with many simple devices and compare it to a design with fewer devices that are newer but more complex. The unit with fewer devices is usually more reliable.
:* '''Can be used to set achievable in-service performance standards''' against which to judge actual performance and stimulate action.
 
The [[telecommunications industry]] has devoted much time over the years to concentrate on developing reliability models for electronic equipment. One such tool is the Automated Reliability Prediction Procedure (ARPP), which is an Excel-spreadsheet software tool that automates the reliability prediction procedures in [http://telecom-info.telcordia.com/site-cgi/ido/docs.cgi?ID=SEARCH&DOCUMENT=SR-332& SR-332, Reliability Prediction Procedure for Electronic Equipment.] FD-ARPP-01 provides suppliers and manufacturers with a tool for making Reliability Prediction Procedure (RPP) calculations. It also provides a means for understanding RPP calculations through the capability of interactive examples provided by the user.
 
The RPP views electronic systems as hierarchical assemblies. Systems are constructed from units that, in turn, are constructed from devices. The methods presented predict reliability at these three hierarchical levels: