Numerical Evaluation of Instantaneous Availability

Frank A. Tillman; Way Kuo; Raja F. Nassar; C. L. Hwang

doi:10.1109/TR.1983.5221495

Numerical Evaluation of Instantaneous Availability

Frank A. Tillman
, Way Kuo
, Raja F. Nassar
, C. L. Hwang

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

12 Citations (Scopus)

Abstract

Instantaneous availability (the probability that the system is operational at any time t) is calculated via renewal theory by representing the system as a 2-state stochastic process; the defined states are on-time and off-time which are combined to form the total cycle time. The analytic solution to the above problem is quite general and can be applied to any system adjusted cycle time and on-time distribution. Using this model, a numerical solution is obtained.

If the on-time and cycle-time are gamma distributed, then the analytic solution, in both complex and real forms, can be derived for the instantaneous availability of a system. if they are not gamma distributed then the analytic approach is difficult (if not impossible) and an alternative method is required. Thus a numerical approach is used, since it is distribution-free. A numerical example of small sample size illustrates the numerical approach. Copyright © 1983 by the Institute of Electrical and Electronics Engineers, Inc.

Original language	English
Pages (from-to)	119-123
Journal	IEEE Transactions on Reliability
Volume	R-32
Issue number	1
DOIs	https://doi.org/10.1109/TR.1983.5221495
Publication status	Published - Apr 1983
Externally published	Yes

Research Keywords

Numerical evaluation
System availability

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10.1109/TR.1983.5221495

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title = "Numerical Evaluation of Instantaneous Availability",

abstract = "Instantaneous availability (the probability that the system is operational at any time t) is calculated via renewal theory by representing the system as a 2-state stochastic process; the defined states are on-time and off-time which are combined to form the total cycle time. The analytic solution to the above problem is quite general and can be applied to any system adjusted cycle time and on-time distribution. Using this model, a numerical solution is obtained. If the on-time and cycle-time are gamma distributed, then the analytic solution, in both complex and real forms, can be derived for the instantaneous availability of a system. if they are not gamma distributed then the analytic approach is difficult (if not impossible) and an alternative method is required. Thus a numerical approach is used, since it is distribution-free. A numerical example of small sample size illustrates the numerical approach. Copyright {\textcopyright} 1983 by the Institute of Electrical and Electronics Engineers, Inc.",

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TY - JOUR

T1 - Numerical Evaluation of Instantaneous Availability

AU - Tillman, Frank A.

AU - Kuo, Way

AU - Nassar, Raja F.

AU - Hwang, C. L.

PY - 1983/4

Y1 - 1983/4

N2 - Instantaneous availability (the probability that the system is operational at any time t) is calculated via renewal theory by representing the system as a 2-state stochastic process; the defined states are on-time and off-time which are combined to form the total cycle time. The analytic solution to the above problem is quite general and can be applied to any system adjusted cycle time and on-time distribution. Using this model, a numerical solution is obtained. If the on-time and cycle-time are gamma distributed, then the analytic solution, in both complex and real forms, can be derived for the instantaneous availability of a system. if they are not gamma distributed then the analytic approach is difficult (if not impossible) and an alternative method is required. Thus a numerical approach is used, since it is distribution-free. A numerical example of small sample size illustrates the numerical approach. Copyright © 1983 by the Institute of Electrical and Electronics Engineers, Inc.

AB - Instantaneous availability (the probability that the system is operational at any time t) is calculated via renewal theory by representing the system as a 2-state stochastic process; the defined states are on-time and off-time which are combined to form the total cycle time. The analytic solution to the above problem is quite general and can be applied to any system adjusted cycle time and on-time distribution. Using this model, a numerical solution is obtained. If the on-time and cycle-time are gamma distributed, then the analytic solution, in both complex and real forms, can be derived for the instantaneous availability of a system. if they are not gamma distributed then the analytic approach is difficult (if not impossible) and an alternative method is required. Thus a numerical approach is used, since it is distribution-free. A numerical example of small sample size illustrates the numerical approach. Copyright © 1983 by the Institute of Electrical and Electronics Engineers, Inc.

KW - Numerical evaluation

KW - System availability

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UR - https://www.scopus.com/record/pubmetrics.uri?eid=2-s2.0-0020734769&origin=recordpage

U2 - 10.1109/TR.1983.5221495

DO - 10.1109/TR.1983.5221495

M3 - RGC 21 - Publication in refereed journal

SN - 0018-9529

VL - R-32

SP - 119

EP - 123

JO - IEEE Transactions on Reliability

JF - IEEE Transactions on Reliability

IS - 1

ER -

Numerical Evaluation of Instantaneous Availability

Abstract

Research Keywords

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