IEC 61703:2016 provides mathematical expressions for selected reliability, availability, maintainability and maintenance support measures defined in IEC 60050192:2015. In addition, it introduces some terms not covered in IEC 60050-192:2015. They are related to aspects of the system of item classes (see hereafter). According to IEC 60050-192:2015, dependability [192-01-22] is the ability of an item to perform as and when required and an item [192-01-01] can be an individual part, component, device, functional unit, equipment, subsystem, or system. To account for mathematical constraints, this standard splits the items between the individual items considered as a whole (e.g. individual components) and the systems made of several individual items. It provides general considerations for the mathematical expressions for systems as well as individual items but the individual items which are easier to model are analysed in more detail with regards to their repair aspects. This standard is mainly applicable to hardware dependability, but many terms and their definitions may be applied to items containing software. This second edition cancels and replaces the first edition published in 2001. This edition constitutes a technical revision. This edition includes the following significant technical changes with respect to the previous edition: – standard made as self containing as possible; – item split between individual items and systems; – generalization of the dependability concepts for systems made of several components [introduction of the conditional failure intensity (Vesely failure rate); – introduction of the state-transition and the Markovian models; – generalization of the availability to production availability]; – introduction of curves to illustrate the various concepts. Keywords: mathematical expressions for dependability

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PDF Pages	PDF Title
130	English CONTENTS
134	FOREWORD
136	INTRODUCTION
137	1 Scope
138	2 Normative references 3 Terms and definitions
141	4 Glossary of symbols and abbreviations 4.1 General 4.2 Acronyms used in this standard
143	4.3 Symbols used in this standard
146	5 General models and assumptions 5.1 Constituents of up and down times Figures Figure 1 – Constituents of up time
147	5.2 Introduction to models and assumptions Figure 2 – Constituents of down time Figure 3 – Acronyms related to failure times
148	5.3 State-transition approach
149	Figure 4 – Simple state-transition diagram
150	5.4 Model and assumptions for non-repairable individual items Figure 5 – Sample realization (chronogram) related to the system in Figure 4 Figure 6 – State-transition diagram of a non-repairable individual item
151	5.5 Assumptions and model for repairable individual items 5.5.1 Assumption for repairable individual items Figure 7 – Sample realization of a non-repairable individual item
152	5.5.2 Instantaneous repair Figure 8 – State-transition diagram of an instantaneously repairable individual item
153	5.5.3 Non-instantaneous repair Figure 9 – Sample realization of a repairable individual item with zero time to restoration Figure 10 – State-transition diagram of a repairable individual item
154	5.6 Continuously operating items (COI) versus intermittently operating individual items (IOI) Figure 11 – Sample realization of a repairable individual item with non-zero time to restoration Figure 12 – Comparison of an enabled time for a COI and an IOI
155	6 Mathematical models and expressions 6.1 Systems 6.1.1 General Figure 13 – Equivalent operating time for IOI items Figure 14 – State-transition graph for a simple redundant system
156	Figure 15 – Markov graph for a simple redundant system Figure 16 – Evolution of the state probabilities related to the Markov model in Figure 15
157	6.1.2 Availability related expressions Figure 17 – Evolution of A(t) and U(t) related to the Markov model in Figure 15
159	Figure 18 – Evolution of the Asti(0, t) related to the Markov model in Figure 15
161	Figure 19 – Instantaneous availability and mean availability of a periodically tested item
162	Figure 20 – Example of a simple production system
163	Figure 21 – Evolution of A(t) and K(t)
164	6.1.3 Reliability related expressions Figure 22 – Illustration of a system reliable behaviour over [0, t]
165	Figure 23 – Illustration of a system reliable behaviour over time interval [t1, t2] Figure 24 – State-transition and Markov graphs for reliability calculations
166	Figure 25 – Evolution of the state probabilities related to the Markov model in Figure 24
167	Figure 26 – Evolution of R(t) and F(t) related to the Markov model in Figure 24
168	6.1.4 Mean operating time between failures [192-05-13] and mean time between failures Figure 27 – Evolution of Asti(0, t) related to the Markov model in Figure 24 Figure 28 – Time between failures versus operating time between failures
169	6.1.5 Instantaneous failure rate [192-05-06] and conditional failure intensity (Vesely failure rate)
171	Figure 29 – Comparison between λ(t) and λV(t) related to the model in Figure 24
172	6.1.6 Failure density and unconditional failure intensity [192-05-08]
174	Figure 30 – Comparison between z(t) and f(t)
175	6.1.7 Comparison of λ(t), λV(t), z(t) and f(t) for high and small MTTRs 6.1.8 Restoration related expressions Figure 31 – Comparison of λ(t), λV(t), z(t) and f(t) for high and small values of MTTRs
177	6.2 Non-repairable individual items 6.2.1 General
178	6.2.2 Instantaneous availability [192-08-01] 6.2.3 Reliability [192-05-05]
179	6.2.4 Instantaneous failure rate [192-05-06]
180	6.2.5 Mean failure rate [192-05-07]
181	6.2.6 Mean operating time to failure [192-05-11]
182	6.3 Repairable individual items with zero time to restoration 6.3.1 General 6.3.2 Reliability [192-05-05]
183	Figure 32 – Illustration of reliable behaviour over [t1, t2] for a zero time to restoration individual item
184	6.3.3 Instantaneous failure intensity [192-05-08] Figure 33 – Sample of possible number of failures at the renewal time t
186	6.3.4 Asymptotic failure intensity [192-05-10]
187	6.3.5 Mean failure intensity [192-05-09]
188	6.3.6 Mean time between failures (see 3.3) 6.3.7 Mean operating time to failure [192-05-11]
189	6.3.8 Mean operating time between failures [192-05-13] 6.3.9 Instantaneous availability [192-08-01], mean availability [192-08-05] and asymptotic availability [192-08-07] 6.3.10 Mean up time [192-08-09]
190	6.4 Repairable individual items with non-zero time to restoration 6.4.1 General 6.4.2 Reliability [192-05-05] Figure 34 – Illustration of reliable behaviour over [t1 ,t2] for a non-zero time to restoration individual item
192	6.4.3 Instantaneous failure intensity [192-05-08] Figure 35 – Evolution of R(t, t + 1/4) Figure 36 – Sample of possible number of failures at the renewal time t
194	Figure 37 – Evolution of the failure intensity z(t)
195	6.4.4 Asymptotic failure intensity [192-05-10]
196	6.4.5 Mean failure intensity [192-05-09]
197	6.4.6 Mean operating time to failure [192-05-11] Figure 38 – Evolution of the mean failure intensity z(t, t + 1/4)
198	6.4.7 Mean time between failures (see 3.3)
199	6.4.8 Mean operating time between failures [192-05-13] 6.4.9 Instantaneous availability [192-08-01] Figure 39 – Illustration of available behaviour at time t for a non-zero time to restoration individual item
201	6.4.10 Instantaneous unavailability [192-08-04] Figure 40 – Evolution of the instantaneous availability A(t) Figure 41 – Illustration of unavailable behaviour at time t for a non-zero time to restoration individual item
202	6.4.11 Mean availability [192-08-05] Figure 42 – Evolution of the instantaneous unavailability U(t)
204	6.4.12 Mean unavailability [192-08-06] Figure 43 – Evolution of the mean availability
205	Figure 44 – Evolution of the mean unavailability
206	6.4.13 Asymptotic availability [192-08-07] 6.4.14 Asymptotic unavailability [192-08-08]
207	6.4.15 Mean up time [192-08-09]
208	Figure 45 – Sample realization of the individual item state Figure 46 – Plot of the up-time hazard rate function
209	6.4.16 Mean down time [192-08-10]
210	6.4.17 Maintainability [192-07-01]
212	6.4.18 Instantaneous repair rate [192-07-20] Figure 47 – Evolution of the maintainability M(t, t+16h)
214	6.4.19 Mean repair time [192-07-21] Figure 48 – Evolution of the lognormal repair rate μ(t)
215	6.4.20 Mean active corrective maintenance time [192-07-22]
216	6.4.21 Mean time to restoration [192-07-23]
217	6.4.22 Mean administrative delay [192-07-26]
218	6.4.23 Mean logistic delay [192-07-27]
219	Annex A (informative) Performance aspects and descriptors Figure A.1 – Performance aspects and descriptors
220	Annex B (informative) Summary of measures related to time to failure Tables Table B.1 – Relations among measures related to time to failure of continuously operating items
221	Table B.2 – Summary of characteristics for some continuous probability distributions of time to failure of continuously operating items
222	Table B.3 – Summary of characteristics for some probability distributions of repair time
223	Annex C (informative) Comparison of some dependability measures for continuously operating items Table C.1 – Comparison of some dependability measures of continuously operating items with constant failure rate λ and restoration rate μR
225	Bibliography

Published By	Publication Date	Number of Pages
BSI	2020	0


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Status	Under Review
Pages	0
Publication Date	2020-02-25
ISBN	978 0 539 09629 3
Standard Number	BS EN 61703:2016 – TC
Title	Tracked Changes. Mathematical expressions for reliability, availability, maintainability and maintenance support terms
Descriptors	Reliability, Quality assurance, Mathematical calculations, Mathematics, Electrical engineering, Availability, Terminology, Mathematical symbols, Maintenance, Quality control, Maintainability
Publisher	BSI
Committee	DS/1
ICS Codes	03.120.30 - Application of statistical methods

BS EN 61703:2016 – TC:2020 Edition

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