Industrial automation standards are to industrial automation what industrial automation is to everything else – they make it all work smoothly and efficiently. With standards developed by ISO, IEC, and ISA, the sum total of standardization efforts in the field is immense. Providing specifications for everything from the foundational network communications profiles all the way through to the tools physically interacting with the products, standards guide the industry, promoting interoperability between vendors and devices, in turn contributing to reliability and efficiency, effectively bringing down costs.
This document identifies technical requirements for information exchange between entities within the reference architecture.
The requirements for information exchange in the following networks are within the scope of this document:
— user network that connects the user entity and the digital twin entity;
— service network that connects sub-entities within the digital twin entity;
— access network that connects the device communication entity to the digital twin entity and to the user entity;
— proximity network that connects the device communication entity to the observable manufacturing elements.
This document specifies the concept and structure of the ISO 16400 series. This series specify a methodology for preparing a template and items of an equipment behaviour catalogue (EBC) as a basis to structure a virtual production system.
ISO 21919 describes interfaces for automated machine tending of at least one computer numerically controlled (CNC) machine by using a machine tending device. These interfaces are the link between automated machine tending devices and machines used for production. The automated machine tending is initiated by either the machine tending system or by the machine.
This document gives an overview and defines the fundamental principles on how the interfaces are set up. It defines the necessary vocabulary and sets the syntax for the structure of signals. It distinguishes between the safety interface, the control interface and project specific extensions.
This document defines three conformance classes and dedicated conformance options. Classes and options consist of a number of signals to simultaneously:
— allow a flexible adaptation of the interface(s) to a project-specific scope of functions;
— tie sets of signals tight enough to avoid unnecessary coordination efforts between suppliers of the machine tending devices and machines.
ISO 21919 concentrates on the control-related and safety-related connections. It does not describe the mechanical connections, it does not determine the transfer physics, a pin assignment, the hardware of the interfaces or measure of communication, e.g. protocol, and it is not intended to be used for communication to a MES (Manufacturing Execution System).
NOTE ISO 21919‑2 deals with the safety interface and control interface, allocating signals to a conformance class and/or conformance option, describing the detailed functions of each signal, describing and displaying the timing interactions between signals in flow charts and showing examples for safety matrices and safety-related functional relationships.
This document describes the general content and structure of the entire QIF information model. It describes the highest level data structures of QIF, that are expanded in Clauses 6 through 12 using data dictionaries and XML schema files. All QIF XML schema files can be found at www.qifstandards.org.
This document also describes practices for forming QIF instance files, called "documents," that support quality workflow scenarios. Its focus is to show how the QIF information model, and data formed into XML instance files, support the entire scope of model based definition manufacturing quality workflow. It describes how the information model is partitioned among the XML schema files and contains all terms used in the subject area clauses.
The purpose of this document is to orient potential users of QIF to the organization of the information model to make their study of the details more rewarding and efficient. It should also help solution providers and users to evaluate QIF for their uses, without needing to go to the lowest technical details of the XML schemas. The information model narrative focuses on the approach to modeling the core data structures of QIF, which model the content of ASME GD&T and ISO GPS, and the plans and results data elements defined in Dimensional Measuring Interface Standards (DMSI) ISO 22093 and ANSI/DMSC DMIS 5.3. The material on XML practices describes consistent design practices to be used by QIF working groups who will be designing new schemas. It should also help data processing experts to write software that writes and reads manufacturing quality data using the XML schemas.
ISO/TR 23087:2018 is the reference framework for the Big Picture project.
The Big Picture aims at monitoring the consistency of published standards and current or future standardization projects.
The Big Picture enables the standardization stakeholders to identify, for each concerned standard or standardization project, the relevant characteristics related to the positioning and impact of the standard or standardization project in the industry.
Although the Big Picture was designed initially for the universe of discourse of ISO/TC 184 and then IEC/TC 65, it applies to manufacturing in general.
IEC TS 61850-1-2:2020, which is a technical specification, is intended for any users but primarily for standardization bodies that are considering using IEC 61850 as a base standard within the scope of their work and are willing to extend it as allowed by the IEC 61850 standards. This document identifies the required steps and high-level requirements in achieving such extensions of IEC 61850 and provides guidelines for the individual steps.
Within that scope, this document addresses the following cases:
• The management of product-level standards for products that have an interface based on IEC 61850
• The management of domain-level standards based on IEC 61850
• The management of transitional standards based on IEC 61850
• The management of private namespaces based on IEC 61850
• The development of standards offering the mapping of IEC 61850 data model at CDC level
• The development and management of IEC 61850 profiles for domains (underlying the role of IEC TR 62361-103 and IEC TR 61850-7-6)
This document includes both technical and process aspects:
On the technical side, this document:
• Reminds the main basic requirements (mostly referring to the appropriate parts of the series which host the requirements or recommendations)
• Lists all possible flexibilities offered by the standards
• Defines which flexibilities are allowed/possible per type of extension cases
On the process side, the document covers:
• The initial analysis of how the existing IEC 61850 object models and/or communication services may be applied and what allowed extensions may be required for utilizing them in new or specific domains (including private ones). The results of that step are expected to be documented
• The extension of the IEC 61850 object models for new domains. The typical associated work is to identify existing logical nodes which can be reused "as is", to determine if existing logical nodes can be extended, or to define new logical nodes
• The purpose and process to use transitional namespaces, which are expected to be merged eventually into an existing standard namespace
• The management of standard namespaces
• The development of private namespaces
IEC TS 61850-2:2019 (E) contains the glossary of specific terms and definitions used in the context of Substation Automation Systems which are standardized in the various parts of the IEC 61850 series.
This second edition cancels and replaces the first edition, published in 2003. This edition constitutes a technical revision. This edition includes the following significant technical changes with respect to the previous edition:
a) definition of new definitions used in the new edition of the IEC 61850 standard series;
b) updating of existing definitions to the new domain power utility automation of the IEC 61850 standard series and to provide homogeneity
c) removal of deprecated definitions (logical device class; generic system state event; substation automation system);
d) provision of clarifications and corrections to the first edition of IEC 61850-2.
This publication is of core relevance for Smart Grid
IEC 61850-4:2011+A1:2020 applies to projects associated with process near automation systems of power utilities (UAS, utility automation system), like e.g. substation automation systems (SAS). It defines the system and project management for UAS systems with communication between intelligent electronic devices (IEDs) in the substation respective plant and the related system requirements. This second edition constitutes a technical revision to align the document more closely with the other parts of the IEC 61850 series, in addition to enlarging the scope from substation automation systems to all utility automation systems. This consolidated version consists of the second edition (2011) and its amendment 1 (2020). Therefore, no need to order amendment in addition to this publication.
This publication is of core relevance for Smart Grid.
IEC 61850-5:2013+AMD1:2022 applies to power utility automation systems with the core part of substation automation systems (SAS); it standardizes the communication between intelligent electronic devices (IEDs) and defines the related system requirements to be supported. The major technical changes with regard to the previous edition are as follows:
- extension from substation automation systems to utility automation systems;
- inclusion of interfaces for communication between substations;
- requirements from communication beyond the boundary of the substation.
IEC/TR 62856:2013 describes features for existing design languages, as well as for enhancing and newly developing design languages belonging to the defined design processes of System on a chip (SoC) which ranges from system level design, SoC design implementation and verification, IP block creation and analog block design down to interface data preparation for manufacturing. Thirty-three design languages have been chosen and each feature of their latest version as of March 2011 is reflected in this report:
UML, Esterel, Rosetta, SystemC, SystemC-AMS, IBIS, CITI, TouchStone, BSDL, System Verilog, VHDL, Verilog HDL, UPF, CPF, e language, PSL, FSDB, SDC, DEF, Open Access, SDF, GDS II, OASIS, STIL, WGL, Verilog-A, Verilog-AMS, SPICE, VHDL-AMS, LEF, Liberty, CDL and IP-XACT.
IEC 62714-4:2020 specifies the integration of logic information as part of an AML model for the data exchange in a heterogenous engineering tool landscape of production systems.
This document specifies three types of logic information: sequencing, behaviour, and interlocking information.
This document deals with the six following sequencing and behaviour logic models (covering the different phases of the engineering process of production systems) and how they are integrated in AML: Gantt chart, activity-on-node network, timing diagram, Sequential Function Chart (SFC), Function Block Diagram (FBD), and mathematical expression.
This document specifies how to model Gantt chart, activity-on-node network, and timing diagram and how they are stored in Intermediate Modelling Layer (IML).
This document specifies how interlocking information is modelled (as interlocking source and target groups) in AML. The interlocking logic model is stored in Function Block Diagram (FBD).
This document specifies the AML logic XML schema that stores the logic models by using IEC 61131-10.
This document specifies how to reference PLC programs stored in PLCopen XML documents.
This document does not define details of the data exchange procedure or implementation requirements for the import/export tools.
IEC PAS 63441:2022 defines the functional architecture and functional model of the Industrial Internet System for industrial applications. It presents the models, structures, activities, and interaction contents between layers of the end, edge, and cloud: infrastructure as a service (IaaS), platform as a service (PaaS), and software as service (SaaS), respectively.
New IEEE Standard - Active. The smart grid interoperability reference model (SGIRM) was developed in IEEE Std 2030™-2011 for systems that integrate, among other assets, distributed energy resources (DER). DER management systems (DERMS) and microgrid controllers are examples of such systems applied in this guide. In the process of applying the SGIRM-2011, elements were added to reflect the changes that have occurred since 2011 in electric grids. These include the increasing deployment of DER both at the distribution system and, when aggregated, at the transmission system, the increasing role of electricity markets, and business and environmental considerations in their deployment. These elements were added to the SGIRM. The SGIRM defines three integrated architectural perspectives (IAP): power systems, communications and information technology, and business and regulatory requirements. The SGIRM facilitates the implementation of interoperability requirements by establishing relationships between elements of the complete installation, regrouped within IAPs, and by identifying the relevant and applicable standards and rules. The SGIRM can be used to complement design approaches for individual elements of a system and facilitates extensibility, scalability, and upgradeability.
New IEEE Standard - Active. Provided in this recommended practice is a comprehensive methodology for technology domain exploration, development of strategy, technology evaluation, implementation, management, operations, program optimization, and successful enterprise scaling for IPA programs while utilizing terminology as established in IEEE Std 2755™-2017 and technology taxonomy as established in IEEE Std 2755.1™-2019. This recommended practice is a compilation of best practices from industry leaders on the proven methods from the initial discovery and exploration of the transformative capabilities of IPA technology through to developing and running an enterprise-wide program.
This part of ISO 13281 specifies a minimum set of services to be provided and interface requirements for creating a MAPLE. The specifications in this part of ISO 13281 are specifically for software developers of MAPLE environments, system integrators, and software tool developers. Specifications that address the needs of users such as program developers, planners and operators in a manufacturing automation environment are outside the scope of this document.
This part of ISO 13281 only specifies the interface at the application layer between MAPLE and software programs.
The creation or deletion of a Manufacturing Database, as well as specifications for the MAPLE Data Dictionary and MAPLE Software Dictionary beyond the dictionary definition schema, are outside the scope of this part of ISO 13281.
ISO 15745 defines an application integration framework - a set of elements and rules for describing integration models and application interoperability profiles.
ISO 15745-1:2003 defines the generic elements and rules for describing integration models and application interoperability profiles, together with their component profiles - process profiles, information exchange profiles, and resource profiles.
NOTE Parts 2, 3 and 4 of ISO 15745 define the technology specific elements and rules for describing both communication network profiles and the communication related aspects of device profiles based upon particular fieldbus technologies; these parts can be used in conjunction with this part to form an application integration framework for a specific fieldbus technology.
This International Standard is applicable to industrial automation applications such as discrete manufacturing, process automation, electronics assembly, semiconductor fabrication, and wide-area material handling. It may also be applicable to other automation and control applications such as utility automation, agriculture, off-road vehicles, medical and laboratory automation, and public transport systems.
ISO 13584-32:2010 specifies an XML-based exchange structure for ISO 13584 compliant data. This exchange structure is called OntoML.
ISO 18629-41:2006 provides definitions written in the language of ISO 18629 for concepts related to activity extensions in the process specification language. The process specification language is aimed at structuring the semantic concepts intrinsic to the capture and exchange of process information related to discrete manufacturing.
ISO 18629-44:2006 provides definitions written in the language of ISO 18629 for concepts related to activity extensions in the process specification language. The process specification language is aimed at structuring the semantic concepts intrinsic to the capture and exchange of process information related to discrete manufacturing.
Specifies the use of the integrated resources necessary for the scope and information requirements for explicit draughting. Annexes A and B are contained in a diskette which accompanies this Standard. It is identical with and has been reproduced from ISO 10303-201:1994. Technical Committee IT-006 has reviewed the content of this publication and in accordance with Standards Australia procedures for reconfirmation, it has been determined that the publication is still valid and does not require change. Certain documents referenced in the publication may have been amended since the original date of publication. Users are advised to ensure that they are using the latest versions of such documents as appropriate, unless advised otherwise in this Reconfirmation Notice. Approved for reconfirmation in accordance with Standards Australia procedures for reconfirmation on 20 August 2013. The following are represented on Technical Committee IT-006: Australia Safety Critical Systems Association Australian Computer Society Australian Industry Group Australian Petroleum Production and Exploration Association Consult Australia Engineers Australia Institute of Chemical Engineers Australia Institute of Instrumentation, Control & Automation Australia Process Control Society The University of Queensland Workplace Health and Safety Queensland
ISO/TS 10303-1024:2004 specifies the application module Product relationship.
The following are within the scope of ISO/TS 10303-1024:2004:
ISO/TS 10303-1074:2005 specifies the application module for Property condition.
The following are within the scope of ISO/TS 10303-1074:2005:
a necessary property condition for membership of a class of product;
a necessary property condition for membership of a class of activity.
ISO/TS 10303-1124:2004 specifies the application module Document structure.
The following are within the scope of ISO/TS 10303-1124:2004:
ISO/TS 10303-1214:2004 specifies the application module for System breakdown.
The following are within the scope of ISO/TS 10303-1214:2004:
ISO/TS 10303-1215:2008 specifies the application module for Physical breakdown.
The following are within the scope of ISO/TS 10303-1215:2008:
ISO/TS 10303-1300:2004 specifies the application module for Work output.
The following are within the scope of ISO/TS 10303-1300:2004:
ISO/TS 10303-1364:2004 specifies the application module Event assignment.
The following are within the scope of ISO/TS 10303-1364:2004:
ISO 20242-4:2011 defines the formatting, syntax and semantic rules for describing
IEC 62439-2:2021 is applicable to high-availability automation networks based on the ISO/IEC/IEEE 8802-3 (IEEE Std 802.3) (Ethernet) technology.
The IEC 62439-2:2021 specifies a recovery protocol based on a ring topology, designed to react deterministically on a single failure of an inter-switch link or switch in the network, under the control of a dedicated media redundancy manager node.
IEC 62948:2017 specifies the system architecture and communication protocol of WIA-FA (Wireless Networks for Industrial Automation - Factory Automation) based on IEEE STD 802.11-2012 physical layer (PHY). This document applies to wireless network systems for factory automation measuring, monitoring and control.
The contents of the corrigendum of March 2021 have been included in this copy.
IEC 63365:2022 applies to products used in the process measurement, control and automation industry. It establishes a concept and requirements for the digital nameplate and provides alternative electronically readable solutions (e.g. 2D codes, RFID or firmware) to current conventional plain text marking on the nameplate or packaging of products.
The digital nameplate information is contained in the electronically readable medium affixed to the product, the packaging or accompanying documents. The digital nameplate information is available offline without Internet connection. After electronic reading, all digital nameplate information is displayed in a human readable text format. The digital nameplate also includes the Identification Link String according to IEC 61406-1 which provides additional online information for the product.
This document does not specify the contents of the conventional nameplate, which are subject to regional or national regulations and standards.
IEC 62832-1:2020 defines the general principles of the Digital Factory framework (DF framework), which is a set of model elements (DF reference model) and rules for modelling production systems.
This DF framework defines:
• a model of production system assets;
• a model of relationships between different production system assets;
• the flow of information about production system assets.
The DF framework does not cover representation of building construction, input resources (such as raw production material, assembly parts), consumables, work pieces in process, nor end products.
It applies to the three types of production processes (continuous control, batch control, and discrete control) in any industrial sector (for example aeronautic industries, automotive, chemicals, wood).
IEC TR 63283-1:2022(E) is to compile a comprehensive collection of base terminology with compatible terms that can become relevant within the scope of Smart Manufacturing. Most of these terms refer to existing definitions in the domain of industrial-process measurement, control and automation and its various subdomains. When multiple similar definitions exist for the exact same term in different standards, this document contains only the preferred definition in the context of Smart Manufacturing. Whenever the existing definitions are not compatible with other terms in this document or when the definition does not fit into the broader scope of Smart Manufacturing, new or modified definitions are given.
This document provides technical characteristics of partial driving automation system according to ISO/SAE PAS 22736 and associated control strategies enabling hands-free driving.
These technical characteristics, together with an appropriate operational design domain enable the proper usage of such partial driving automation systems which is supervised by drivers.
This document does not address performance limits, verification and validation of such systems.
CSA Preface This is the first edition of CAN/CSA-IEC 62443-2-4, Security for industrial automation and control systems — Part 2-4: Security program requirements for IACS service providers , which is an adoption without modification of the identically titled IEC (International Electrotechnical Commission) Standard 62443-2-4 (first edition, 2015-06). For brevity, this Standard will be referred to as "CAN/CSA-IEC 62443-2-4" throughout. This Standard is one in a series of Standards developed by IEC/TC 65 on industrial automation networking security that are being adopted by CSA Group. This Standard specifies requirements for security capabilities for IACS service providers that they can offer to asset owners during the integration and maintenance activities of an Automatic Solution. This Standard uses terminology and concepts specified in the following: a) CAN/CSA-IEC/TS 62443-1-1:17, Industrial communication networks — Network and system security — Part 1-1: Terminology, concepts and models; and b) CAN/CSA-IEC 62443-2-1:17, Industrial communication networks — Network and system security — Part 2-1: Establishing an industrial automation and control system security program. This Standard was reviewed for Canadian adoption by the CSA Technical Committee on Information Technology, under the jurisdiction of the CSA Strategic Steering Committee on Information and Communications Technology, and has been formally approved by the Technical Committee. This Standard has been developed in compliance with Standards Council of Canada requirements for National Standards of Canada. It has been published as a National Standard of Canada by CSA Group. Scope This part of IEC 62443-2-4 specifies requirements for security capabilities for IACS service providers that they can offer to the asset owner during integration and maintenance activities of an Automation Solution. NOTE 1 The term "Automation Solution" is used as a proper noun (and therefore capitalized) in this part of IEC 62443 to prevent confusion with other uses of this term. Collectively, the security capabilities offered by an IACS service provider are referred to as its Security Program. In a related specification, IEC 62443-2-1 describes requirements for the Security Management System of the asset owner. NOTE 2 In general, these security capabilities are policy, procedure, practice and personnel related. Figure 2 illustrates how the integration and maintenance capabilities relate to the IACS and the control system product that is integrated into the Automation Solution. Some of these capabilities reference security measures defined in IEC 62443-3-3 that the service provider must ensure are supported in the Automation Solution (either included in the control system product or separately added to the Automation Solution). In Figure 2, the Automation Solution is illustrated to contain a Basic Process Control System (BPCS), optional Safety Instrumented System (SIS), and optional supporting applications, such as advanced control. The dashed boxes indicate that these components are "optional". NOTE 3 The term "process" in BPCS may apply to a variety of industrial processes, including continuous processes and manufacturing processes. NOTE 4 Clause 4.1.4 describes profiles and how they can be used by industry groups and other organizations to adapt this International Standard to their specific environments, including environments not based on an IACS. NOTE 5 Automation Solutions typically have a single control system (product), but they are not restricted to do so. In general, the Automation Solution is the set of hardware and software, independent of product packaging, that is used to control a physical process (e.g. continuous or manufacturing) as defined by the asset owner. -------------------------------------------------------------------------------------------------------------------------------- Préface CSA Ce document constitue la première édition de CAN/CSA-IEC 62443-2-4, Sécurité des automatismes industriels et des systèmes de commande — Partie 2-4 : Exigences de programme de sécurité pour les fournisseurs de service IACS . Il s’agit de l’adoption, sans modifications, de la norme IEC (Commission Électrotechnique Internationale) 62443-2-4 (première édition, 2015-06) qui porte le même titre. Par souci de brièveté, tout au long de ce document, il sera appelé « CAN/CSA-IEC 62443-2-4 ». Cette norme fait partie d’une série de normes élaborées par l’IEC/TC 65 qui portent sur la sécurité des réseaux relatifs aux automatismes industriels et qui sont adoptées par Groupe CSA. Cette norme spécifie les exigences de capacités de sécurité pour les fournisseurs de service IACS qu’ils peuvent proposer aux propriétaires d'actif pendant les activités d'intégration et de maintenance d'une Solution d’Automatisation. Cette norme utilise la terminologie et les concepts précisés dans les documents suivants : a) CAN/CSA-IEC/TS 62443-1-1:17, Industrial communication networks — Network and system security — Part 1-1: Terminology, concepts and models; et b) CAN/CSA-IEC 62443-2-1:17, Réseaux industriels de communication — Sécurité dans les réseaux et les systèmes — Partie 2-1 : Établissement d’un programme de sécurité pour les systèmes d’automatisation et de commande industrielles. Cette norme a été révisée en vue de son adoption au Canada par le Comité technique CSA sur les technologies de l’information, sous l’autorité du Comité directeur stratégique CSA sur les technologies de l’information et les communications, et a été officiellement approuvée par le Comité technique. Cette norme a été élaborée conformément aux exigences du Conseil canadien des normes relatives aux Normes nationales du Canada. Cette norme a été publiée en tant que Norme nationale du Canada par Groupe CSA. Domaine d’application La présente partie de l'IEC 62443-2-4 spécifie les exigences de capacités de sécurité pour les fournisseurs de service IACS qu’ils peuvent proposer au propriétaire d'actif pendant les activités d'intégration et de maintenance d'une Solution d’Automatisation. NOTE 1 Dans la présente partie de l’IEC 62443, le terme ‘’Solution d’Automatisation’’ est utilisé comme un nom propre (et par conséquent écrit en majuscule) pour éviter toute confusion avec d’autres usages de ce terme. De manière collective, les capacités de sécurité offertes par un fournisseur de service IACS sont appelées Programme de sécurité. Une spécification associée, l'IEC 62443-2-1 décrit les exigences pour le Système de gestion de sécurité du propriétaire d'actif. NOTE 2 En général, ces capacités de sécurité sont liées à la politique, la procédure, la pratique et au personnel. La Figure 2 représente la relation entre les capacités d'intégration et de maintenance et l'IACS ainsi que le produit de système de commande intégré à la Solution d'Automatisation. Certaines de ces mesures de sécurité de référence en matière de capacités définies dans l’IEC 62443-3-3 que le fournisseur de service doit assurer sont prises en charge dans la Solution d'Automatisation (soit incluses dans le produit de système de commande soit séparément ajoutées à la Solution d'Automatisation). La Figure 2 représente la Solution d'Automatisation qui contient un Système de Commande de Processus de Base (BPCS), un Système Equipé pour la Sécurité (SIS) facultatif et des Applications de Prise en Charge facultatives telles que la commande avancée. Les cases en pointillés indiquent que ces composants sont «facultatifs». NOTE 3 Le terme «processus» dans BPCS peut s’appliquer à différents processus industriels, y compris les processus continus et les procédés de fabrication. NOTE 4 L’Article 4.1.4 décrit les profils et la façon dont des groupes industriels et autres organisations peuvent les utiliser pour adapter la présente Norme internationale à leurs environnements spécifiques, y compris les environnements non fondés sur un IACS. NOTE 5 En règle générale, les Solutions d'Automatisation disposent d’un seul système de commande (produit), sans toutefois s’y limiter. En général, la Solution d'Automatisation comprend l'ensemble des matériels et logiciels, indépendants de l'emballage du produit, qui est utilisé pour contrôler un processus physique (continu ou de fabrication, par exemple) tel que défini par le propriétaire d’actif.
SECURITY FOR INDUSTRIAL AUTOMATION AND CONTROL SYSTEMS – PART 4-2: Technical security requirements for IACS components
See the rest of the IEC 60654 series, dealing with industrial-process measurement and control – operating conditions.
See the rest of the IEC 60770 series, dealing with transmitters for use in industrial-process control systems.
IEC 61069-1:2016 defines the terminology and outlines basic concepts in the assessment of a basic process control system (BPCS) and a basic discrete control system (BDCS). These two general system types cover the areas of discrete, batch and continuous applications. In IEC 61069 these two, BPCS and BDCS, together are referred to as "basic control system(s)", (BCS). This second edition cancels and replaces the first edition published in 1991. This edition constitutes a technical revision. This edition includes the following significant technical changes with respect to the previous edition: - Reorganization of the material of IEC 61069-1:1991 to make the overall set of standards more organized and consistent; - IEC TS 62603-1:2014 has been incorporated into this edition.
IEC 61158-1:2023 specifies the generic concept of fieldbuses. This document also presents an overview and guidance for the IEC 61158 eries by: explaining the structure and content of the IEC 61158 series; relating the structure of the IEC 61158 series to the ISO/IEC 7498-1 OSI Basic Reference Model; showing the logical structure of the IEC 61784 series; showing how to use parts of the IEC 61158 series in combination with the IEC 61784 series; providing explanations of some aspects of the IEC 61158 series that are common to the type specific parts of the IEC 61158 5 series including the application layer service description concepts and the generic fieldbus data types.
See the rest of the IEC 61298 series, dealing with process measurement and control devices – general methods and procedures for evaluating performance.
See the rest of the IEC 61508 series, dealing with functional safety of electrical/electronic/programmable electronic safety-related systems.
IEC 61784-1:2019 (E) defines a set of protocol specific communication profiles based primarily on the IEC 61158 series, to be used in the design of devices involved in communications in factory manufacturing and process control. This fifth edition cancels and replaces the fourth edition published in 2014 it constitutes a technical revision. The main changes are: • update of the dated references to the IEC 61158 series, to IEC 61784 2, to the IEC 61784 3 series, to the IEC 61784-5 series and to IEC 61918 throughout the document; • update of selection tables CPF 2, CPF 4 and CPF 8
IEC 61987-1:2024 is available as IEC 61987-1:2024 RLV which contains the International Standard and its Redline version, showing all changes of the technical content compared to the previous edition. IEC 61987-1:2024 defines a generic structure in which product features of industrial process measurement devices shall be arranged, in order to facilitate the understanding of product descriptions when they are transferred from one party to another. It applies to the production of catalogues supplied by the manufacturer of such devices and helps the user to formulate their requirements. This document will also serve as a reference document for all future standards which are concerned with process measuring equipment. In addition, this document also provides a basic structure for the production of further standards listing the properties of process control equipment, for example, for actuators and infrastructure devices. This edition includes the following significant technical changes with respect to the previous edition: a) Addition of a subclause “Digital communication” in Clause 5, in order to allow a more comprehensive description of the properties of such an interface; b) Alignment of clause headings, as described in the introduction, to correspond with those of the IEC CDD.
See the rest of the IEC 62264 series, enterprise-control system integration, as well as adoptions by multiple national standards bodies.
IEC 62381:2024 defines requirements and checklists for the factory acceptance test (FAT), the factory integration test (FIT), the site acceptance test (SAT), and the site integration test (SIT). These tests are carried out to demonstrate that the automation system meets the requirements of the applicable specification. This document provides a means for all parties, including the owner, the buyer, and the vendor, to clearly establish and agree on the scope of activities and responsibilities involved in performing these tests in order to achieve a timely delivery and acceptance of the automation system. The activities specified in this document can be used to develop test plans adapted to the specific requirements of the process/plant/equipment. The annexes of this document contain checklists which are available for consideration when preparing specific test procedures and documentation for a specific automation system. This edition includes the following significant technical changes with respect to the previous edition: a) General re-organization of the standard; b) Current technology incorporated; c) Optional factory integration test (FIT) added; d) Replaced the forms in the annexes with detailed checklists of activities which can be used to develop project-specific test plans; and e) Provided additional references to other applicable standards.
IEC 62453-1:2016 presents an overview and guidance for the IEC 62453 series. It - explains the structure and content of the IEC 62453 series (see Clause 5); - provides explanations of some aspects of the IEC 62453 series that are common to many of the parts of the series; - describes the relationship to some other standards. This second edition cancels and replaces the first edition published in 2009. This edition constitutes a technical revision. This edition includes the following significant technical changes with respect to the previous edition: introduction of a new implementation technology (defined in IEC 62453-42).
This document provides an overview of the ISO 10303 series. This document defines the architectural principles of product information representation and exchange used in the ISO 10303 series. It specifies the characteristics of the various sets of parts in the ISO 10303 series and the relationships among them. The following are within the scope of this document: — scope statement for the ISO 10303 series as a whole; — overview of the ISO 10303 series; — architectures of the ISO 10303 series; — structure of the ISO 10303 series; — overview of data specification methods used in the ISO 10303 series; NOTE This includes the EXPRESS data specification language and graphical presentation of product information models. — introduction to the ISO 10303 series: — integrated resources (IRs); — application interpreted constructs (AICs); — application modules (AMs); — application domain models (ADMs); — Core model; — business object models (deprecated); — application protocols (APs); — implementation methods; — usage guides; — conformance testing methodology and framework; — abstract test suites (ATSs); — scheme for identification of schemas and other information objects defined in the ISO 10303 series.
See the rest of the ISO 23570 series, dealing with industrial automation systems and integration – distributed installation in industrial applications.
See the rest of the ISO 16100 series, dealing with industrial automation systems and integration – manufacturing software capability profiling for interoperability.
See the rest of the ISO 20242 series, dealing with industrial automation systems and integration – service interface for testing applications.
See the rest of the ISO 15531 series, dealing with industrial automation systems and integration – industrial manufacturing management data.
See the rest of the ISO 13584 series, dealing with industrial automation systems and integration – parts library, as well as adoptions by multiple national standards bodies.
Covers real-time batch, discrete and continuous process automation systems. Defines regulatory, event-driven and time-driven control system actions. Encompasses both digital and analog control devices in addition to non-control actions (for example, operator messages and batch end reports). Encompasses both normal and abnormal operational requirements of systems and shows the interactions between them. Uses a set of terms that relate directly to the languages commonly used by plant operators. Excludes interactions with higher-level systems. Within the parameters of this scope, the standard is intended to: Establish functional requirements specifications for control software documentation that covers the classes of industrial automation equipment and systems consisting of distributed control systems, programmable controllers and industrial personal computers (see Figure 1). Provide techniques for documenting control system software. The software to be generated is a function of the computer system chosen for a particular project. The documentation procedure set forth in this standard is independent of the hardware/software system that is chosen. Provide a basis for validation of run-time application software after it is developed and tested to ensure that the initial requirement specification has been met. The documentation resulting from use of this standard: Can be used for control software definition, design, testing and validation. Is not intended to require specialized knowledge of any particular engineering or computer science discipline to develop or understand.
This technical report presents descriptive user and market-related requirements of wireless communication in factory automation applications. It provides references to all six ISA100 usage classes; use case descriptions and comparisons; descriptions of factory automation topologies; and recommendations for attributes and values for existing, emerging, and conceptual solutions for wireless communications as applied to factory automation applications.
This Part 1 Technical Report, in combination with the forthcoming Part 2, discusses trustworthiness associated with the use of wireless technology in industrial automation systems. Specifically excluded are those attributes that may be in common with wired systems and are therefore covered elsewhere, or attributes that are specific to other application domains such as healthcare applications. Also excluded are those attributes associated with ancillary issues such as health effects of RF or component materials (such as batteries). For this document, trustworthiness encompasses attributes associated with reliability, security and resiliency.
This document presents an architecture model for interconnecting automation system elements over untrusted backhaul networks. The focus is on wireless physical la yer but is not limited to wireless.