fbpx
Wikipedia

IEC 61508

April 09, 2024

IEC 61508 is an international standard published by the International Electrotechnical Commission (IEC) consisting of methods on how to apply, design, deploy and maintain automatic protection systems called safety-related systems. It is titled Functional Safety of Electrical/Electronic/Programmable Electronic Safety-related Systems (E/E/PE, or E/E/PES).

IEC 61508 is a basic functional safety standard applicable to all industries. It defines functional safety as: “part of the overall safety relating to the EUC (Equipment Under Control) and the EUC control system which depends on the correct functioning of the E/E/PE safety-related systems, other technology safety-related systems and external risk reduction facilities.” The fundamental concept is that any safety-related system must work correctly or fail in a predictable (safe) way.

The standard has two fundamental principles:

  1. An engineering process called the safety life cycle is defined based on best practices in order to discover and eliminate design errors and omissions.
  2. A probabilistic failure approach to account for the safety impact of device failures.

The safety life cycle has 16 phases which roughly can be divided into three groups as follows:

  1. Phases 1–5 address analysis
  2. Phases 6–13 address realisation
  3. Phases 14–16 address operation.

All phases are concerned with the safety function of the system.

The standard has seven parts:

  • Parts 1–3 contain the requirements of the standard (normative)
  • Part 4 contains definitions
  • Parts 5–7 are guidelines and examples for development and thus informative.

Central to the standard are the concepts of probabilistic risk for each safety function. The risk is a function of frequency (or likelihood) of the hazardous event and the event consequence severity. The risk is reduced to a tolerable level by applying safety functions which may consist of E/E/PES, associated mechanical devices, or other technologies. Many requirements apply to all technologies but there is strong emphasis on programmable electronics especially in Part 3.

IEC 61508 has the following views on risks:

  • Zero risk can never be reached, only probabilities can be reduced
  • Non-tolerable risks must be reduced (ALARP)
  • Optimal, cost effective safety is achieved when addressed in the entire safety lifecycle

Specific techniques ensure that mistakes and errors are avoided across the entire life-cycle. Errors introduced anywhere from the initial concept, risk analysis, specification, design, installation, maintenance and through to disposal could undermine even the most reliable protection. IEC 61508 specifies techniques that should be used for each phase of the life-cycle. The seven parts of the first edition of IEC 61508 were published in 1998 and 2000. The second edition was published in 2010.

Hazard and risk analysis edit

The standard requires that hazard and risk assessment be carried out for bespoke systems: 'The EUC (equipment under control) risk shall be evaluated, or estimated, for each determined hazardous event'.

The standard advises that 'Either qualitative or quantitative hazard and risk analysis techniques may be used' and offers guidance on a number of approaches. One of these, for the qualitative analysis of hazards, is a framework based on 6 categories of likelihood of occurrence and 4 of consequence.

Categories of likelihood of occurrence

Category Definition Range (failures per year)
Frequent Many times in lifetime > 10−3
Probable Several times in lifetime 10−3 to 10−4
Occasional Once in lifetime 10−4 to 10−5
Remote Unlikely in lifetime 10−5 to 10−6
Improbable Very unlikely to occur 10−6 to 10−7
Incredible Cannot believe that it could occur < 10−7

Consequence categories

Category Definition
Catastrophic Multiple loss of life
Critical Loss of a single life
Marginal Major injuries to one or more persons
Negligible Minor injuries at worst

These are typically combined into a risk class matrix

Consequence
Likelihood Catastrophic Critical Marginal Negligible
Frequent I I I II
Probable I I II III
Occasional I II III III
Remote II III III IV
Improbable III III IV IV
Incredible IV IV IV IV

Where:

  • Class I: Unacceptable in any circumstance;
  • Class II: Undesirable: tolerable only if risk reduction is impracticable or if the costs are grossly disproportionate to the improvement gained;
  • Class III: Tolerable if the cost of risk reduction would exceed the improvement;
  • Class IV: Acceptable as it stands, though it may need to be monitored.

Safety integrity level edit

Main article: Safety integrity level

The safety integrity level (SIL) provides a target to attain for each safety function. A risk assessment effort yields a target SIL for each safety function. For any given design the achieved SIL is evaluated by three measures:

1. Systematic Capability (SC) which is a measure of design quality. Each device in the design has an SC rating. The SIL of the safety function is limited to smallest SC rating of the devices used. Requirement for SC are presented in a series of tables in Part 2 and Part 3. The requirements include appropriate quality control, management processes, validation and verification techniques, failure analysis etc. so that one can reasonably justify that the final system attains the required SIL.

2. Architecture Constraints which are minimum levels of safety redundancy presented via two alternative methods - Route 1h and Route 2h.

3. Probability of Dangerous Failure Analysis[1]

Probabilistic analysis edit

The probability metric used in step 3 above depends on whether the functional component will be exposed to high or low demand:

  • high demand is defined as more than once per year and low demand is defined as less than or equal to once per year (IEC-61508-4).
  • For functions that operate continuously (continuous mode) or functions that operate frequently (high demand mode), SIL specifies an allowable frequency of dangerous failure.
  • For functions that operate intermittently (low demand mode), SIL specifies an allowable probability that the function will fail to respond on demand.

Note the difference between function and system. The system implementing the function might be in operation frequently (like an ECU for deploying an air-bag), but the function (like air-bag deployment) might be in demand intermittently.

SIL Low demand mode:
average probability of failure on demand 		High demand or continuous mode:
probability of dangerous failure per hour
1 ≥ 10−2 to < 10−1 ≥ 10−6 to < 10−5
2 ≥ 10−3 to < 10−2 ≥ 10−7 to < 10−6
3 ≥ 10−4 to < 10−3 ≥ 10−8 to < 10−7 (1 dangerous failure in 1140 years)
4 ≥ 10−5 to < 10−4 ≥ 10−9 to < 10−8

IEC 61508 certification edit

Certification is third party attestation that a product, process, or system meets all requirements of the certification program. Those requirements are listed in a document called the certification scheme. IEC 61508 certification programs are operated by impartial third party organizations called certification bodies (CB). These CBs are accredited to operate following other international standards including ISO/IEC 17065 and ISO/IEC 17025. Certification bodies are accredited to perform the auditing, assessment, and testing work by an accreditation body (AB). There is often one national AB in each country. These ABs operate per the requirements of ISO/IEC 17011, a standard that contains requirements for the competence, consistency, and impartiality of accreditation bodies when accrediting conformity assessment bodies. ABs are members of the International Accreditation Forum (IAF) for work in management systems, products, services, and personnel accreditation or the International Laboratory Accreditation Cooperation (ILAC) for laboratory accreditation. A Multilateral Recognition Arrangement (MLA) between ABs will ensure global recognition of accredited CBs. IEC 61508 certification programs have been established by several global Certification Bodies. Each has defined their own scheme based upon IEC 61508 and other functional safety standards. The scheme lists the referenced standards and specifies procedures which describes their test methods, surveillance audit policy, public documentation policies, and other specific aspects of their program. IEC 61508 certification programs are being offered globally by several recognized CBs including Intertek, SGS-TÜV Saar, TÜV Nord, TÜV Rheinland, TÜV SÜD and UL.

Industry/application specific variants edit

Automotive edit

ISO 26262 is an adaptation of IEC 61508 for Automotive Electric/Electronic Systems. It is being widely adopted by the major car manufacturers.[2]

Before the launch of ISO 26262, the development of software for safety related automotive systems was predominantly covered by the Motor Industry Software Reliability Association (MISRA) guidelines.[3] The MISRA project was conceived to develop guidelines for the creation of embedded software in road vehicle electronic systems.[3] A set of guidelines for the development of vehicle based software was published in November 1994.[4] This document provided the first automotive industry interpretation of the principles of the, then emerging, IEC 61508 standard.[3]

Today MISRA is most widely known for its guidelines on how to use the C and C++ languages.[5] MISRA C has gone on to become the de facto standard for embedded C programming in the majority of safety-related industries, and is also used to improve software quality even where safety is not the main consideration.

Rail edit

IEC 62279 provides a specific interpretation of IEC 61508 for railway applications. It is intended to cover the development of software for railway control and protection including communications, signaling and processing systems. EN 50128 and EN 50657 are equivalent CENELEC standards of IEC 62279.[6]

Process industries edit

The process industry sector includes many types of manufacturing processes, such as refineries, petrochemical, chemical, pharmaceutical, pulp and paper, and power. IEC 61511 is a technical standard which sets out practices in the engineering of systems that ensure the safety of an industrial process through the use of instrumentation.

Power plants edit

IEC 61513 provides requirements and recommendations for the instrumentation and control for systems important to safety of nuclear power plants. It indicates the general requirements for systems that contain conventional hardwired equipment, computer-based equipment or a combination of both types of equipment. An overview list of safety norms specific for nuclear power plants is published by ISO.[7]

Machinery edit

IEC 62061 is the machinery-specific implementation of IEC 61508. It provides requirements that are applicable to the system level design of all types of machinery safety-related electrical control systems and also for the design of non-complex subsystems or devices.

Testing software edit

Software written in accordance with IEC 61508 may need to be unit tested, depending up on the SIL it needs to achieve. The main requirement in Unit Testing is to ensure that the software is fully tested at the function level and that all possible branches and paths are taken through the software. In some higher SIL level applications, the software code coverage requirement is much tougher and an MC/DC code coverage criterion is used rather than simple branch coverage. To obtain the MC/DC (modified condition/decision coverage) coverage information, one will need a Unit Testing tool, sometimes referred to as a Software Module Testing tool.

See also edit

References edit

  1. ^ Control Systems Safety Evaluation and Reliability. ISA. 2010. ISBN 978-1-934394-80-9.
  2. ^ Hamann, Reinhold; Sauler, Jürgen; Kriso, Stefan; Grote, Walter; Mössinger, Jürgen (2009-04-20). "Application of ISO 26262 in Distributed Development ISO 26262 in Reality". SAE Technical Paper Series. 1. Warrendale, PA: SAE International. doi:10.4271/2009-01-0758.
  3. ^ a b c "MISRA Web site > MISRA Home > A brief history of MISRA". www.misra.org.uk. Retrieved 2021-02-23.
  4. ^ Development Guidelines for Vehicle Based Software. MISRA. 1994. ISBN 0952415607.
  5. ^ "MISRA Web site > News". www.misra.org.uk. Retrieved 2021-02-23.
  6. ^ Hadj-Mabrouk, Habib (1 November 2020). "Application of Case-Based Reasoning to the safety assessment of critical software used in rail transport". Safety Science. 131: 104928. doi:10.1016/j.ssci.2020.104928. ISSN 0925-7535.
  7. ^ "ISO - 27.120.20 - Nuclear power plants. Safety". www.iso.org. Retrieved 2021-02-23.

Further reading edit

Related safety standards edit

Textbooks edit

  • W. Goble, "Control Systems Safety Evaluation and Reliability" (3rd Edition ISBN 978-1-934394-80-9, Hardcover, 458 pages).
  • I. van Beurden, W. Goble, "Safety Instrumented System Design-Techniques and Design Verification" (1st Edition ISBN 978-1-945541-43-8, 430 pages).
  • M.J.M. Houtermans, "SIL and Functional Safety in a Nutshell" (Risknowlogy Best Practices, 1st Edition, eBook in PDF, ePub, and iBook format, 40 Pages) SIL and Functional Safety in a Nutshell - eBook introducing SIL and Functional Safety
  • M. Medoff, R. Faller, "Functional Safety - An IEC 61508 SIL 3 Compliant Development Process" (3rd Edition, ISBN 978-1-934977-08-8 Hardcover, 371 pages, www.exida.com)
  • C. O'Brien, L. Stewart, L. Bredemeyer, "Final Elements in Safety Instrumented Systems - IEC 61511 Compliant Systems and IEC 61508 Compliant Products" (1st Edition, 2018, ISBN 978-1-934977-18-7, Hardcover, 305 pages, www.exida.com)
  • Münch, Jürgen; Armbrust, Ove; Soto, Martín; Kowalczyk, Martin. “Software Process Definition and Management“, Springer, 2012.
  • M.Punch, "Functional Safety for the Mining Industry – An Integrated Approach Using AS(IEC)61508, AS(IEC) 62061 and AS4024.1." (1st Edition, ISBN 978-0-9807660-0-4, in A4 paperback, 150 pages).
  • D.Smith, K Simpson, "Safety Critical Systems Handbook: A Straightforward Guide to Functional Safety, IEC 61508 (2010 Edition) And Related Standards, Including Process IEC 61511 and Machinery IEC 62061 and ISO 13849" (3rd Edition ISBN 978-0-08-096781-3, Hardcover, 288 Pages).

External links edit

  • IEC 61508-1:2010 Functional safety of electrical/electronic/programmable electronic safety-related systems- Parts 1
  • "IEC 61508" at International Electrotechnical Commission
  • IEC Functional Safety zone
  • 61508 Association A cross-industry group of organizations with an interest in achieving a dependable and cost-effective method for demonstrating compliance with IEC 61508 and related standards.
  1. ^ "Relationship between ISO 26262 and IEC 61508". ez.analog.com. Retrieved 2021-04-11.
  2. ^ "Automotive vs Industrial Functional Safety". ez.analog.com. Retrieved 2021-04-11.
  3. ^ "IEC 60730-1:2013+AMD1:2015+AMD2:2020 CSV | IEC Webstore". webstore.iec.ch. Retrieved 2021-04-11.

April 09, 2024
61508, this, article, includes, list, general, references, lacks, sufficient, corresponding, inline, citations, please, help, improve, this, article, introducing, more, precise, citations, april, 2021, learn, when, remove, this, template, message, internationa. This article includes a list of general references but it lacks sufficient corresponding inline citations Please help to improve this article by introducing more precise citations April 2021 Learn how and when to remove this template message IEC 61508 is an international standard published by the International Electrotechnical Commission IEC consisting of methods on how to apply design deploy and maintain automatic protection systems called safety related systems It is titled Functional Safety of Electrical Electronic Programmable Electronic Safety related Systems E E PE or E E PES IEC 61508 is a basic functional safety standard applicable to all industries It defines functional safety as part of the overall safety relating to the EUC Equipment Under Control and the EUC control system which depends on the correct functioning of the E E PE safety related systems other technology safety related systems and external risk reduction facilities The fundamental concept is that any safety related system must work correctly or fail in a predictable safe way The standard has two fundamental principles An engineering process called the safety life cycle is defined based on best practices in order to discover and eliminate design errors and omissions A probabilistic failure approach to account for the safety impact of device failures The safety life cycle has 16 phases which roughly can be divided into three groups as follows Phases 1 5 address analysis Phases 6 13 address realisation Phases 14 16 address operation All phases are concerned with the safety function of the system The standard has seven parts Parts 1 3 contain the requirements of the standard normative Part 4 contains definitions Parts 5 7 are guidelines and examples for development and thus informative Central to the standard are the concepts of probabilistic risk for each safety function The risk is a function of frequency or likelihood of the hazardous event and the event consequence severity The risk is reduced to a tolerable level by applying safety functions which may consist of E E PES associated mechanical devices or other technologies Many requirements apply to all technologies but there is strong emphasis on programmable electronics especially in Part 3 IEC 61508 has the following views on risks Zero risk can never be reached only probabilities can be reduced Non tolerable risks must be reduced ALARP Optimal cost effective safety is achieved when addressed in the entire safety lifecycleSpecific techniques ensure that mistakes and errors are avoided across the entire life cycle Errors introduced anywhere from the initial concept risk analysis specification design installation maintenance and through to disposal could undermine even the most reliable protection IEC 61508 specifies techniques that should be used for each phase of the life cycle The seven parts of the first edition of IEC 61508 were published in 1998 and 2000 The second edition was published in 2010 Contents 1 Hazard and risk analysis 2 Safety integrity level 2 1 Probabilistic analysis 3 IEC 61508 certification 4 Industry application specific variants 4 1 Automotive 4 2 Rail 4 3 Process industries 4 4 Power plants 4 5 Machinery 5 Testing software 6 See also 7 References 8 Further reading 8 1 Related safety standards 8 2 Textbooks 9 External linksHazard and risk analysis editThe standard requires that hazard and risk assessment be carried out for bespoke systems The EUC equipment under control risk shall be evaluated or estimated for each determined hazardous event The standard advises that Either qualitative or quantitative hazard and risk analysis techniques may be used and offers guidance on a number of approaches One of these for the qualitative analysis of hazards is a framework based on 6 categories of likelihood of occurrence and 4 of consequence Categories of likelihood of occurrence Category Definition Range failures per year Frequent Many times in lifetime gt 10 3Probable Several times in lifetime 10 3 to 10 4Occasional Once in lifetime 10 4 to 10 5Remote Unlikely in lifetime 10 5 to 10 6Improbable Very unlikely to occur 10 6 to 10 7Incredible Cannot believe that it could occur lt 10 7Consequence categories Category DefinitionCatastrophic Multiple loss of lifeCritical Loss of a single lifeMarginal Major injuries to one or more personsNegligible Minor injuries at worstThese are typically combined into a risk class matrix ConsequenceLikelihood Catastrophic Critical Marginal NegligibleFrequent I I I IIProbable I I II IIIOccasional I II III IIIRemote II III III IVImprobable III III IV IVIncredible IV IV IV IVWhere Class I Unacceptable in any circumstance Class II Undesirable tolerable only if risk reduction is impracticable or if the costs are grossly disproportionate to the improvement gained Class III Tolerable if the cost of risk reduction would exceed the improvement Class IV Acceptable as it stands though it may need to be monitored Safety integrity level editMain article Safety integrity level The safety integrity level SIL provides a target to attain for each safety function A risk assessment effort yields a target SIL for each safety function For any given design the achieved SIL is evaluated by three measures 1 Systematic Capability SC which is a measure of design quality Each device in the design has an SC rating The SIL of the safety function is limited to smallest SC rating of the devices used Requirement for SC are presented in a series of tables in Part 2 and Part 3 The requirements include appropriate quality control management processes validation and verification techniques failure analysis etc so that one can reasonably justify that the final system attains the required SIL 2 Architecture Constraints which are minimum levels of safety redundancy presented via two alternative methods Route 1h and Route 2h 3 Probability of Dangerous Failure Analysis 1 Probabilistic analysis edit The probability metric used in step 3 above depends on whether the functional component will be exposed to high or low demand high demand is defined as more than once per year and low demand is defined as less than or equal to once per year IEC 61508 4 For functions that operate continuously continuous mode or functions that operate frequently high demand mode SIL specifies an allowable frequency of dangerous failure For functions that operate intermittently low demand mode SIL specifies an allowable probability that the function will fail to respond on demand Note the difference between function and system The system implementing the function might be in operation frequently like an ECU for deploying an air bag but the function like air bag deployment might be in demand intermittently SIL Low demand mode average probability of failure on demand High demand or continuous mode probability of dangerous failure per hour1 10 2 to lt 10 1 10 6 to lt 10 52 10 3 to lt 10 2 10 7 to lt 10 63 10 4 to lt 10 3 10 8 to lt 10 7 1 dangerous failure in 1140 years 4 10 5 to lt 10 4 10 9 to lt 10 8IEC 61508 certification editCertification is third party attestation that a product process or system meets all requirements of the certification program Those requirements are listed in a document called the certification scheme IEC 61508 certification programs are operated by impartial third party organizations called certification bodies CB These CBs are accredited to operate following other international standards including ISO IEC 17065 and ISO IEC 17025 Certification bodies are accredited to perform the auditing assessment and testing work by an accreditation body AB There is often one national AB in each country These ABs operate per the requirements of ISO IEC 17011 a standard that contains requirements for the competence consistency and impartiality of accreditation bodies when accrediting conformity assessment bodies ABs are members of the International Accreditation Forum IAF for work in management systems products services and personnel accreditation or the International Laboratory Accreditation Cooperation ILAC for laboratory accreditation A Multilateral Recognition Arrangement MLA between ABs will ensure global recognition of accredited CBs IEC 61508 certification programs have been established by several global Certification Bodies Each has defined their own scheme based upon IEC 61508 and other functional safety standards The scheme lists the referenced standards and specifies procedures which describes their test methods surveillance audit policy public documentation policies and other specific aspects of their program IEC 61508 certification programs are being offered globally by several recognized CBs including Intertek SGS TUV Saar TUV Nord TUV Rheinland TUV SUD and UL Industry application specific variants editAutomotive edit ISO 26262 is an adaptation of IEC 61508 for Automotive Electric Electronic Systems It is being widely adopted by the major car manufacturers 2 Before the launch of ISO 26262 the development of software for safety related automotive systems was predominantly covered by the Motor Industry Software Reliability Association MISRA guidelines 3 The MISRA project was conceived to develop guidelines for the creation of embedded software in road vehicle electronic systems 3 A set of guidelines for the development of vehicle based software was published in November 1994 4 This document provided the first automotive industry interpretation of the principles of the then emerging IEC 61508 standard 3 Today MISRA is most widely known for its guidelines on how to use the C and C languages 5 MISRA C has gone on to become the de facto standard for embedded C programming in the majority of safety related industries and is also used to improve software quality even where safety is not the main consideration Rail edit IEC 62279 provides a specific interpretation of IEC 61508 for railway applications It is intended to cover the development of software for railway control and protection including communications signaling and processing systems EN 50128 and EN 50657 are equivalent CENELEC standards of IEC 62279 6 Process industries edit The process industry sector includes many types of manufacturing processes such as refineries petrochemical chemical pharmaceutical pulp and paper and power IEC 61511 is a technical standard which sets out practices in the engineering of systems that ensure the safety of an industrial process through the use of instrumentation Power plants edit IEC 61513 provides requirements and recommendations for the instrumentation and control for systems important to safety of nuclear power plants It indicates the general requirements for systems that contain conventional hardwired equipment computer based equipment or a combination of both types of equipment An overview list of safety norms specific for nuclear power plants is published by ISO 7 Machinery edit IEC 62061 is the machinery specific implementation of IEC 61508 It provides requirements that are applicable to the system level design of all types of machinery safety related electrical control systems and also for the design of non complex subsystems or devices Testing software editSoftware written in accordance with IEC 61508 may need to be unit tested depending up on the SIL it needs to achieve The main requirement in Unit Testing is to ensure that the software is fully tested at the function level and that all possible branches and paths are taken through the software In some higher SIL level applications the software code coverage requirement is much tougher and an MC DC code coverage criterion is used rather than simple branch coverage To obtain the MC DC modified condition decision coverage coverage information one will need a Unit Testing tool sometimes referred to as a Software Module Testing tool See also editFunctional safety Safety standards FMEDA Spurious trip level Time triggered system A software architecture used to achieve IEC 61508 compliance Software qualityReferences edit Control Systems Safety Evaluation and Reliability ISA 2010 ISBN 978 1 934394 80 9 Hamann Reinhold Sauler Jurgen Kriso Stefan Grote Walter Mossinger Jurgen 2009 04 20 Application of ISO 26262 in Distributed Development ISO 26262 in Reality SAE Technical Paper Series 1 Warrendale PA SAE International doi 10 4271 2009 01 0758 a b c MISRA Web site gt MISRA Home gt A brief history of MISRA www misra org uk Retrieved 2021 02 23 Development Guidelines for Vehicle Based Software MISRA 1994 ISBN 0952415607 MISRA Web site gt News www misra org uk Retrieved 2021 02 23 Hadj Mabrouk Habib 1 November 2020 Application of Case Based Reasoning to the safety assessment of critical software used in rail transport Safety Science 131 104928 doi 10 1016 j ssci 2020 104928 ISSN 0925 7535 ISO 27 120 20 Nuclear power plants Safety www iso org Retrieved 2021 02 23 Further reading editRelated safety standards edit ISO 26262 is an adaption of IEC 61508 1 with minor differences 2 IEC 60730 3 Household DO 178C Aerospace Textbooks edit W Goble Control Systems Safety Evaluation and Reliability 3rd Edition ISBN 978 1 934394 80 9 Hardcover 458 pages I van Beurden W Goble Safety Instrumented System Design Techniques and Design Verification 1st Edition ISBN 978 1 945541 43 8 430 pages M J M Houtermans SIL and Functional Safety in a Nutshell Risknowlogy Best Practices 1st Edition eBook in PDF ePub and iBook format 40 Pages SIL and Functional Safety in a Nutshell eBook introducing SIL and Functional Safety M Medoff R Faller Functional Safety An IEC 61508 SIL 3 Compliant Development Process 3rd Edition ISBN 978 1 934977 08 8 Hardcover 371 pages www exida com C O Brien L Stewart L Bredemeyer Final Elements in Safety Instrumented Systems IEC 61511 Compliant Systems and IEC 61508 Compliant Products 1st Edition 2018 ISBN 978 1 934977 18 7 Hardcover 305 pages www exida com Munch Jurgen Armbrust Ove Soto Martin Kowalczyk Martin Software Process Definition and Management Springer 2012 M Punch Functional Safety for the Mining Industry An Integrated Approach Using AS IEC 61508 AS IEC 62061 and AS4024 1 1st Edition ISBN 978 0 9807660 0 4 in A4 paperback 150 pages D Smith K Simpson Safety Critical Systems Handbook A Straightforward Guide to Functional Safety IEC 61508 2010 Edition And Related Standards Including Process IEC 61511 and Machinery IEC 62061 and ISO 13849 3rd Edition ISBN 978 0 08 096781 3 Hardcover 288 Pages External links editIEC 61508 1 2010 Functional safety of electrical electronic programmable electronic safety related systems Parts 1 IEC 61508 at International Electrotechnical Commission IEC Functional Safety zone 61508 Association A cross industry group of organizations with an interest in achieving a dependable and cost effective method for demonstrating compliance with IEC 61508 and related standards Relationship between ISO 26262 and IEC 61508 ez analog com Retrieved 2021 04 11 Automotive vs Industrial Functional Safety ez analog com Retrieved 2021 04 11 IEC 60730 1 2013 AMD1 2015 AMD2 2020 CSV IEC Webstore webstore iec ch Retrieved 2021 04 11 Retrieved from https en wikipedia org w index php title IEC 61508 amp oldid 1204593596, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.