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SIST EN 61970-301:2014

(Main)

Energy management system application program interface (EMS-API) - Part 301: Common information model (CIM) base

Energy management system application program interface (EMS-API) - Part 301: Common information model (CIM) base

The common information model (CIM) is an abstract model that represents all the major objects in an electric utility enterprise typically involved in utility operations. By providing a standard way of representing power system resources as object classes and attributes, along with their relationships, the CIM facilitates the integration of Energy Management System (EMS) applications developed independently by different vendors, between entire EMS systems developed independently, or between an EMS system and other systems concerned with different aspects of power system operations, such as generation or distribution management. SCADA is modeled to the extent necessary to support power system simulation and inter-control center communication. The CIM facilitates integration by defining a common language (i.e. semantics) based on the CIM to enable these applications or systems to access public data and exchange information independent of how such information is represented internally. The object classes represented in the CIM are abstract in nature and may be used in a wide variety of applications. The use of the CIM goes far beyond its application in an EMS. This standard should be understood as a tool to enable integration in any domain where a common power system model is needed to facilitate interoperability and plug compatibility between applications and systems independent of any particular implementation. Due to the size of the complete CIM, the object classes contained in the CIM are grouped into a number of logical Packages, each of which represents a certain part of the overall power system being modeled. Collections of these Packages are progressed as separate International Standards. This particular International Standard specifies a Base set of packages which provide a logical view of the functional aspects of Energy Management System (EMS) information within the electric utility enterprise that is shared between all applications. Other standards specify more specific parts of the model that are needed by only certain applications. Subclause 4.2 below provides the current grouping of packages into standards documents.

Schnittstelle für Anwendungsprogramme für Netzführungssysteme (EMS-API) - Teil 301: Allgemeines Informationsmodell (CIM)

Interface de programmation d'application pour système de gestion d'énergie (EMS-API) - Part 301: Base de modèle d'information commun (CIM)

La CEI 61970-301:2013 définit le CIM qui est un modèle abstrait représentant tous les objets principaux d'une entreprise de distribution d'électricité habituellement nécessaires aux opérations d'une entreprise d'électricité. En fournissant une façon normalisée de représenter des ressources de réseaux électriques comme classes et attributs d'objets ainsi que leurs relations, le CIM facilite l'intégration des applications de l'EMS développées de façon indépendante par différents fournisseurs, entre des systèmes EMS complets développés de façon indépendante ou entre un système EMS et d'autres systèmes concernés par différents aspects des opérations d'un réseau électrique tels que la gestion de la production ou de la distribution. Le système SCADA est modélisé dans toute la mesure nécessaire pour prendre en charge la simulation des systèmes énergétiques et la communication entre des centres de commande. Le CIM facilite l'intégration en définissant un langage commun (c'est-à-dire une sémantique) fondé sur le modèle CIM pour permettre à ces applications ou systèmes d'accéder aux données publiques et d'échanger des informations indépendamment de la représentation interne de ces informations. Les modifications techniques majeures par rapport à l'édition précédente sont les suivantes:  - les modèles de transformateurs ont été modifiés pour qu'ils soient adaptés à une utilisation dans les domaines de la distribution et du transport;  - l'ajout d'une approche de dénomination plus générale et plus claire et suppression des attributs ambigus liés à la dénomination;  - des modèles de fils de phase pour les composants ont été améliorés pour décrire les connexions et les attributs spécifiques de phase interne;  - des modèles de présentation des diagrammes ont été ajoutés pour faciliter l'échange des informations sur la présentation des diagrammes.

Aplikacijski programski vmesnik za sistem upravljanja z energijo (EMS-API) - 301. del: Osnova skupnega informacijskega modela (CIM)

Skupni informacijski model (CIM) je abstraktni model, ki predstavlja vse glavne objekte v elektropodjetju, ki običajno opravlja javno službo. Z zagotavljanjem standardnega načina predstavitve elektroenergetskih virov kot objektnih razredov in atributov, skupaj z njihovimi povezavami, model CIM olajšuje integracijo aplikacij sistema upravljanja z energijo (EMS), ki so jih neodvisno razvili različni prodajalci, med celotnimi samostojno razvitimi sistemi EMS ali med sistemom EMS in drugimi sistemi, ki se ukvarjajo z drugimi vidiki delovanja elektroenergetskega sistema, kot je na primer upravljanje proizvodnje ali distribucije. SCADA je modeliran v obsegu, potrebnem za podporo simulacije elektroenergetskega sistema in komunikacije centra za medsebojni nadzor. CIM olajšuje integracijo z opredelitvijo skupnega jezika (tj. semantike), osnovanega na CIM, ki omogoča, da imajo te aplikacije ali sistemi dostop do javnih podatkov in izmenjujejo informacije neodvisno od tega, kako so te informacije izražene interno. Objektni razredi, predstavljeni v modelu CIM, so abstraktni in se lahko uporabljajo v različnih aplikacijah. Uporaba modela CIM presega njegovo uporabo v sistemu EMS: Ta standard naj bi se razumel kot orodje za omogočanje integracije na vseh področjih, kjer je potreben skupni model elektroenergetskega sistema za lažjo interoperabilnost in združljivost vtičev med aplikacijami in sistemi, neodvisno od dejanske izvedbe. Zaradi velikosti celotnega modela CIM so objektni razredi, ki jih vsebuje CIM, združeni v številne logične pakete, pri čemer vsak predstavlja določen del celotnega elektroenergetskega sistema. Zbirke teh paketov so obravnavane kot ločeni mednarodni standardi. Ta mednarodni standard določa osnovni nabor paketov, ki nudijo logični pogled funkcionalnih vidikov informacij sistema upravljanja z energijo (EMS) v javnem elektro podjetju, ki si jih delijo vse aplikacije. Drugi standardi določajo bolj specifične dele modela, ki jih potrebujejo samo nekatere aplikacije. Spodnja točka 4.2 podaja trenutno združevanje paketov v standardne dokumente.

General Information

Status
Withdrawn
Publication Date
18-Sep-2014
Withdrawal Date
14-Nov-2019
ICS
29.240.30 - Control equipment for electric power systems
35.200 - Interface and interconnection equipment
Technical Committee
PSE - Power systems management
Current Stage
9900 - Withdrawal (Adopted Project)
Start Date
14-Nov-2019
Due Date
07-Dec-2019
Completion Date
15-Nov-2019
Ref Project
EN 61970-301:2014 - Energy management system application program interface (EMS-API) - Part 301: Common information model (CIM) base

Relations

Replaced By
SIST EN 61970-301:2017 - Energy management system application program interface (EMS-API) - Part 301: Common information model (CIM) base
Effective Date
01-Jun-2017
Replaces
SIST EN 61970-301:2014 - Energy management system application program interface (EMS-API) - Part 301: Common information model (CIM) base
Effective Date
28-Jan-2023
Replaces
SIST EN 61970-301:2014 - Energy management system application program interface (EMS-API) - Part 301: Common information model (CIM) base
Effective Date
07-Jun-2022

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SLOVENSKI STANDARD
SIST EN 61970-301:2014
01-oktober-2014
Aplikacijski programski vmesnik za sistem upravljanja z energijo (EMS-API) - 301.
del: Osnova skupnega informacijskega modela (CIM)
Energy management system application program interface (EMS-API) - Part 301:
Common information model (CIM) base
Interface de programmation d'application pour système de gestion d'énergie (EMS-API) -
Part 301: Base de modèle d'information commun (CIM)
Ta slovenski standard je istoveten z: EN 61970-301:2014
ICS:
29.240.30 Krmilna oprema za Control equipment for electric
elektroenergetske sisteme power systems
35.200 Vmesniška in povezovalna Interface and interconnection
oprema equipment
SIST EN 61970-301:2014 en
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

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SIST EN 61970-301:2014

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SIST EN 61970-301:2014


EUROPEAN STANDARD EN 61970-301

NORME EUROPÉENNE

EUROPÄISCHE NORM
July 2014
ICS 33.200 Supersedes EN 61970-301:2013
English Version
Energy management system application program interface
(EMS-API) - Part 301: Common information model (CIM) base
(IEC 61970-301:2013)
Interface de programmation d'application pour système de Schnittstelle für Anwendungsprogramme für
gestion d'énergie (EMS-API) - Part 301: Base de modèle Netzführungssysteme (EMS-API) - Teil 301: Allgemeines
d'information commun (CIM) Informationsmodell (CIM)
(CEI 61970-301:2013) (IEC 61970-301:2013)
This European Standard was approved by CENELEC on 2014-01-17. CENELEC members are bound to comply with the CEN/CENELEC
Internal Regulations which stipulate the conditions for giving this European Standard the status of a national standard without any alteration.
Up-to-date lists and bibliographical references concerning such national standards may be obtained on application to the CEN-CENELEC
Management Centre or to any CENELEC member.
This European Standard exists in three official versions (English, French, German). A version in any other language made by translation
under the responsibility of a CENELEC member into its own language and notified to the CEN-CENELEC Management Centre has the
same status as the official versions.
CENELEC members are the national electrotechnical committees of Austria, Belgium, Bulgaria, Croatia, Cyprus, the Czech Republic,
Denmark, Estonia, Finland, Former Yugoslav Republic of Macedonia, France, Germany, Greece, Hungary, Iceland, Ireland, Italy, Latvia,
Lithuania, Luxembourg, Malta, the Netherlands, Norway, Poland, Portugal, Romania, Slovakia, Slovenia, Spain, Sweden, Switzerland,
Turkey and the United Kingdom.



European Committee for Electrotechnical Standardization
Comité Européen de Normalisation Electrotechnique
Europäisches Komitee für Elektrotechnische Normung
CEN-CENELEC Management Centre: Avenue Marnix 17, B-1000 Brussels
© 2014 CENELEC All rights of exploitation in any form and by any means reserved worldwide for CENELEC Members.
 Ref. No. EN 61970-301:2014 E

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SIST EN 61970-301:2014
EN 61970-301:2014 - 2 -
Foreword
The text of document 57/1395/FDIS, future edition 5 of IEC 61970-301, prepared by IEC TC 57 "Power
systems management and associated information exchange" was submitted to the IEC-CENELEC
parallel vote and approved by CENELEC as EN 61970-301:2014.
The following dates are fixed:
(dop) 2015-01-18
• latest date by which the document has
to be implemented at national level by
publication of an identical national
standard or by endorsement
• latest date by which the national (dow) 2017-01-17
standards conflicting with the
document have to be withdrawn

This document supersedes EN 61970-301:2013.
Attention is drawn to the possibility that some of the elements of this document may be the subject of
patent rights. CENELEC [and/or CEN] shall not be held responsible for identifying any or all such patent
rights.
This document has been prepared under a mandate given to CENELEC by the European Commission
and the European Free Trade Association.
Endorsement notice
The text of the International Standard IEC 61970-301:2013 was approved by CENELEC as a European
Standard without any modification.
In the official version, for Bibliography, the following notes have to be added for the standards indicated:

IEC 61968-11 NOTE  Harmonised in EN 61968-11.
IEC 61970-501 NOTE  Harmonised as EN 61970-501.

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SIST EN 61970-301:2014
- 3 - EN 61970-301:2014
Annex ZA
(normative)

Normative references to international publications
with their corresponding European publications

The following documents, in whole or in part, are normatively referenced in this document and are
indispensable for its application. For dated references, only the edition cited applies. For undated
references, the latest edition of the referenced document (including any amendments) applies.

NOTE  When an international publication has been modified by common modifications, indicated by (mod), the relevant EN/HD
applies.

Publication Year Title EN/HD Year

IEC 60050 (Series) International Electrotechnical Vocabulary - -
(IEV)


IEC 60870-6 (Series) Telecontrol equipment and systems - EN 60870-6 (Series)
Part 6-802: Telecontrol protocols compatible
with ISO standards and ITU-T
recommendations - TASE.2 Object models


IEC 61850 (Series) Communication networks and systems for EN 61850 (Series)
power utility automation


IEC 61850-7-3 2010 Communication networks and systems for EN 61850-7-3 2011
power utility automation -
Part 7-3: Basic communication structure -
Common data classes


IEC 61850-7-4 2010 Communication networks and systems for EN 61850-7-4 2010
power utility automation -
Part 7-4: Basic communication structure -
Compatible logical node classes and data
object classes


IEC 61968 (Series) Application integration at electric utilities - EN 61968 (Series)
System interfaces for distribution
management


IEC/TS 61970-2 Energy management system application CLC/TS 61970-2
program interface (EMS-API) -
Part 2: Glossary


IEC 62325 (Series) Framework for energy market EN 62325 (Series)
communications

UML 2.0 - Object Object Management Group: UML 2.0 - -
Group Management Specification

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SIST EN 61970-301:2014

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SIST EN 61970-301:2014




IEC 61970-301

®


Edition 5.0 2013-12




INTERNATIONAL



STANDARD




NORME



INTERNATIONALE
colour

inside










Energy management system application program interface (EMS-API) –

Part 301: Common information model (CIM) base




Interface de programmation d'application pour système de gestion d'énergie

(EMS-API) –

Partie 301: Base de modèle d'information commun (CIM)















INTERNATIONAL

ELECTROTECHNICAL

COMMISSION


COMMISSION

ELECTROTECHNIQUE

PRICE CODE
INTERNATIONALE

CODE PRIX XH


ICS 33.200 ISBN 978-2-8322-1291-2



Warning! Make sure that you obtained this publication from an authorized distributor.

Attention! Veuillez vous assurer que vous avez obtenu cette publication via un distributeur agréé.

® Registered trademark of the International Electrotechnical Commission
Marque déposée de la Commission Electrotechnique Internationale

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SIST EN 61970-301:2014
– 2 – 61970-301  IEC:2013
CONTENTS
FOREWORD . 27
INTRODUCTION . 29
1 Scope . 31
2 Normative references . 31
3 Terms and definitions . 32
4 CIM specification . 33
4.1 CIM modeling notation . 33
4.2 CIM packages . 33
4.3 CIM classes and relationships . 35
4.3.1 Classes . 35
4.3.2 Generalization . 36
4.3.3 Simple association . 37
4.3.4 Aggregation . 37
4.4 CIM model concepts and examples . 38
4.4.1 Concepts . 38
4.4.2 Containment, equipment hierarchies and naming . 38
4.4.3 Names model . 40
4.4.4 Connectivity model . 41
4.4.5 Inheritance hierarchy . 44
4.4.6 Transformer model . 45
4.4.7 Transformer tap modeling . 48
4.4.8 Phase wire modeling . 52
4.4.9 Cuts, clamps and jumpers model . 53
4.4.10 Measurements and controls . 56
4.4.11 Regulating control models . 61
4.5 Modeling guidelines . 62
4.5.1 Modeling for change . 62
4.5.2 Process for amendments to the CIM . 62
4.5.3 Changes to the CIM UML model . 63
4.5.4 Changes to the CIM standards documents . 63
4.5.5 Deprecations . 63
4.5.6 CIM profiles . 63
4.6 Modeling tools . 64
4.7 User implementation conventions . 64
4.7.1 Conventions beyond UML . 64
4.7.2 Number of Terminals for ConductingEquipment objects . 64
4.8 CIM modeling examples . 64
5 Detailed model . 65
5.1 Overview . 65
5.2 Context . 65
6 Top package IEC61970 . 67
6.1 General . 67
6.2 IEC61970CIMVersion root class . 67
6.3 Package Domain . 68
6.3.1 General . 68
6.3.2 ActivePower datatype . 73

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SIST EN 61970-301:2014
61970-301  IEC:2013 – 3 –
6.3.3 ActivePowerChangeRate datatype . 73
6.3.4 Admittance datatype . 73
6.3.5 AngleDegrees datatype . 73
6.3.6 AngleRadians datatype . 74
6.3.7 ApparentPower datatype . 74
6.3.8 Boolean primitive . 74
6.3.9 Capacitance datatype . 74
6.3.10 Conductance datatype . 75
6.3.11 ConductancePerLength datatype . 75
6.3.12 CostPerEnergyUnit datatype . 75
6.3.13 CostPerVolume datatype . 75
6.3.14 CostRate datatype . 76
6.3.15 Currency enumeration . 76
6.3.16 CurrentFlow datatype . 77
6.3.17 Damping datatype . 77
6.3.18 Date primitive . 78
6.3.19 DateInterval compound . 78
6.3.20 DateTime primitive . 78
6.3.21 DateTimeInterval compound . 78
6.3.22 Decimal primitive . 78
6.3.23 Displacement datatype . 78
6.3.24 Duration primitive . 79
6.3.25 Float primitive . 79
6.3.26 FloatQuantity datatype . 79
6.3.27 Frequency datatype . 79
6.3.28 Hours datatype . 79
6.3.29 Impedance datatype . 80
6.3.30 Inductance datatype . 80
6.3.31 Integer primitive . 80
6.3.32 IntegerQuantity datatype . 80
6.3.33 KiloActivePower datatype . 80
6.3.34 Length datatype . 81
6.3.35 Minutes datatype . 81
6.3.36 Money datatype . 81
6.3.37 PU datatype . 81
6.3.38 PerCent datatype . 82
6.3.39 Pressure datatype . 82
6.3.40 Reactance datatype . 82
6.3.41 ReactancePerLength datatype . 83
6.3.42 ReactivePower datatype . 83
6.3.43 RealEnergy datatype . 83
6.3.44 Resistance datatype . 83
6.3.45 ResistancePerLength datatype . 84
6.3.46 RotationSpeed datatype . 84
6.3.47 Seconds datatype . 84
6.3.48 Speed datatype . 85
6.3.49 String primitive . 85
6.3.50 StringQuantity datatype . 85
6.3.51 Susceptance datatype . 85

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SIST EN 61970-301:2014
– 4 – 61970-301  IEC:2013
6.3.52 SusceptancePerLength datatype . 86
6.3.53 Temperature datatype . 86
6.3.54 Time primitive . 86
6.3.55 TimeInterval compound . 86
6.3.56 UnitMultiplier enumeration . 87
6.3.57 UnitSymbol enumeration . 87
6.3.58 Voltage datatype . 88
6.3.59 VoltagePerReactivePower datatype . 88
6.3.60 Volume datatype . 89
6.3.61 VolumeFlowRate datatype . 89
6.3.62 WaterLevel datatype . 89
6.3.63 Weight datatype . 89
6.4 Package Core . 90
6.4.1 General . 90
6.4.2 BasePower . 94
6.4.3 BaseVoltage . 94
6.4.4 BasicIntervalSchedule . 95
6.4.5 Bay . 96
6.4.6 BreakerConfiguration enumeration . 97
6.4.7 BusbarConfiguration enumeration . 97
6.4.8 ConductingEquipment . 97
6.4.9 ConnectivityNode. 98
6.4.10 ConnectivityNodeContainer . 99
6.4.11 Curve . 99
6.4.12 CurveData root class . 100
6.4.13 CurveStyle enumeration . 101
6.4.14 Equipment . 101
6.4.15 EquipmentContainer . 102
6.4.16 GeographicalRegion . 103
6.4.17 IdentifiedObject root class . 103
6.4.18 IrregularIntervalSchedule . 104
6.4.19 IrregularTimePoint root class . 105
6.4.20 Name root class . 105
6.4.21 NameType root class . 106
6.4.22 NameTypeAuthority root class . 106
6.4.23 OperatingParticipant . 107
6.4.24 OperatingShare root class . 107
6.4.25 PhaseCode enumeration. 108
6.4.26 PowerSystemResource . 109
6.4.27 PsrList . 109
6.4.28 PSRType . 110
6.4.29 RegularIntervalSchedule . 110
6.4.30 RegularTimePoint root class . 111
6.4.31 ReportingGroup . 112
6.4.32 ReportingSuperGroup . 112
6.4.33 SubGeographicalRegion . 113
6.4.34 Substation . 113
6.4.35 Terminal . 114
6.4.36 VoltageLevel . 115

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SIST EN 61970-301:2014
61970-301  IEC:2013 – 5 –
6.5 Package DiagramLayout . 116
6.5.1 General . 116
6.5.2 Diagram . 117
6.5.3 DiagramObject . 118
6.5.4 DiagramObjectGluePoint root class . 119
6.5.5 DiagramObjectPoint root class . 119
6.5.6 DiagramObjectStyle . 120
6.5.7 OrientationKind enumeration . 120
6.5.8 TextDiagramObject . 120
6.5.9 VisibilityLayer . 121
6.6 Package OperationalLimits . 122
6.6.1 General . 122
6.6.2 ActivePowerLimit . 123
6.6.3 ApparentPowerLimit. 124
6.6.4 BranchGroup . 125
6.6.5 BranchGroupTerminal root class . 125
6.6.6 CurrentLimit . 126
6.6.7 OperationalLimit . 126
6.6.8 OperationalLimitDirectionKind enumeration . 127
6.6.9 OperationalLimitSet . 127
6.6.10 OperationalLimitType . 128
6.6.11 VoltageLimit . 128
6.7 Package Topology . 129
6.7.1 General . 129
6.7.2 BusNameMarker . 133
6.7.3 TopologicalIsland . 134
6.7.4 TopologicalNode . 135
6.8 Package Wires . 136
6.8.1 General . 136
6.8.2 ACLineSegment . 149
6.8.3 ACLineSegmentPhase . 151
6.8.4 AsynchronousMachine . 152
6.8.5 Breaker . 154
6.8.6 BusbarSection . 155
6.8.7 Clamp . 156
6.8.8 CompositeSwitch . 157
6.8.9 CompositeSwitchType datatype . 158
6.8.10 Conductor . 158
6.8.11 Connector . 159
6.8.12 CoolantType enumeration . 160
6.8.13 Cut . 160
6.8.14 DCLineSegment . 162
6.8.15 Disconnector . 163
6.8.16 EnergyConsumer . 164
6.8.17 EnergyConsumerPhase . 166
6.8.18 EnergySource . 166
6.8.19 FrequencyConverter . 167
6.8.20 Fuse . 169
6.8.21 Ground . 170

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SIST EN 61970-301:2014
– 6 – 61970-301  IEC:2013
6.8.22 GroundDisconnector . 171
6.8.23 Jumper . 172
6.8.24 Junction . 173
6.8.25 Line . 174
6.8.26 LoadBreakSwitch . 175
6.8.27 MutualCoupling . 176
6.8.28 OperatingMode datatype . 177
6.8.29 PerLengthImpedance . 177
6.8.30 PerLengthPhaseImpedance . 178
6.8.31 PerLengthSequenceImpedance . 179
6.8.32 PhaseImpedanceData root class . 179
6.8.33 PhaseShuntConnectionKind enumeration . 180
6.8.34 PhaseTapChanger . 180
6.8.35 PhaseTapChangerAsymetrical . 181
6.8.36 PhaseTapChangerLinear . 183
6.8.37 PhaseTapChangerNonLinear .
...

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The IEC 61970-401 document describes how the IEC 61970-450 to -499, IEC TS 61970-600 and IEC 61970-600 profile standards as well as any other CIM based profile specifications are structured and created. Profile documents describe a subset of the canonical CIM dedicated to a specific data exchange, the canonical CIM is described in the IEC 61970-300 series documents as well as the IEC 61968-11.
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Tools that process data described by profiles created according to this document will need a machine readable version of the profiles, also called syntactical profile. IEC 61970-501 is an RDFS based serialization intended for this. Hence profiling tools shall support the generation of profiles in the IEC 61970-501 serialisation format. [...]

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SIST EN IEC 61968-100:2022(Main)
Application integration at electric utilities - System interfaces for distribution management - Part 100: Implementation profiles
EN IEC 61968-100:2022

1.1 General
This International Standard is Part 100 of IEC 61968. It defines how messages may be exchanged between co-operating systems in order to facilitate the transfer of application-specific data. Such application-specific data include but are not limited to the message payloads defined in IEC 61968 (Parts 3-9 and Part 13), IEC 61970 and IEC 62325.
1.2 About This International Standard
This International Standard provides normative definitions for:
- a set of message archetypes (clause 5);
- a set of message exchange patterns that both sending and receiving systems are expected to implement (clause 6);
- the exact format of the messages that are to be transmitted over the various integration technologies including a precise description of the information that each message must contain (clause 7);
- a set of constraints and conventions to which applications must adhere in order to facilitate message exchange using IEC 61968-100 (clause 8);
-  the details of how IEC 61968-100 messages should be implemented using various underlying transport mechanisms (clause 9).
1.3 What is not covered by this International Standard
Security considerations lie outside the scope of IEC 61968-100. This document defers to the IEC 62351 series for definitions and practices relating to the secure transmission of messages.
1.4 Future Considerations
1.4.1 Choice of Encoding Mechanisms
IEC 61968-100:2021 prescribes XML as the normative encoding mechanism for all messages defined by this International Standard.
Future editions of IEC 61968-100 may specify additional normative encoding methods including support for IEC 62361-104. The latter defines encodings to facilitate the exchange of information in the form of JSON documents whose semantics are defined by the IEC CIM and whose syntax is defined by an IETF JSON schema.
1.4.2 Choice of Web Service Technologies
IEC 61968-100:2021 provides normative definitions for the use of SOAP Web Services (clause 9.2) and Java Messaging Service (clause 9.3) for the transport of messages.
Future editions of IEC 61968-100 may specify additional normative web service technologies such as REST.

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SIST EN IEC 61970-301:2020/A1:2022(Amendment)
Energy management system application program interface (EMS-API) - Part 301: Common information model (CIM) base
EN IEC 61970-301:2020/A1:2022
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SIST EN IEC 61970-456:2022(Main)
Energy management system application program interface (EMS-API) - Part 456: Solved power system state profiles
EN IEC 61970-456:2022

This part of IEC 61970 belongs to the IEC 61970-450 to IEC 61970-499 series that, taken as a
whole, defines at an abstract level the content and exchange mechanisms used for data
transmitted between power system analyses applications, control centres and/or control centre
components.
The purpose of this document is to rigorously define the subset of classes, class attributes, and
roles from the CIM necessary to describe the result of state estimation, power flow and other
similar applications that produce a steady-state solution of a power network, under a set of use
cases which are included informatively in this document.
This document is intended for two distinct audiences, data producers and data recipients, and
can be read from those two perspectives. From the standpoint of model export software used
by a data producer, the document defines how a producer may describe an instance of a
network case in order to make it available to some other program. From the standpoint of a
consumer, the document defines what that importing software must be able to interpret in order
to consume power flow cases.
There are many different use cases for which use of this document is expected and they differ
in the way that the document will be applied in each case. Implementers are expected to
consider what use cases they wish to cover in order to know the extent of different options they
must cover. As an example, the profiles defined in this document will be used in some cases to
exchange starting conditions rather than solved conditions, so if this is an important use case,
it means that a consumer application needs to be able to handle an unsolved state as well as
one which has met some solution criteria

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SIST EN IEC 61970-600-2:2022(Main)
Energy management system application program interface (EMS-API) - Part 600-2: Common Grid Model Exchange Specification (CGMES) - Exchange profiles specification
EN IEC 61970-600-2:2021

This part of IEC 61970-600 defines the profiles included in the Common Grid Model Exchange
Standard (CGMES) that are based on IEC 61970-450-series and IEC 61968-13 profiles. This
document refers to the IEC 61970-450-series and IEC 61968-13 profiles only in cases where
they are identical. If the referenced profile is not yet published, this document includes the
profile definition and related constraints’ definitions. In the case where a CGMES profile makes
restriction on the referenced profile, the restriction is defined in this document.
The equipment boundary profile (EQBD) is the only profile that is not part of IEC 61970-450-
series and IEC 61968-13 profiles. This profile is deprecated as modifications have been made
to align between EQBP and the equipment profile (EQ). Although the updated EQBD is
addressing the requirement that boundary also can be located inside a substation, which will
be the case for many Distribution System Operators (DSOs), additional information would need
to be exchanged. For instance, system integrity protection schemes, that can be shared by
multiple utility would require another way of boundary handling. In this document EQBD is
included in CGMES only to create better backwards compatibility with previous version of the
CGMES.
The machine-readable documentation that supports model driven development of the profiles
defined in this part are generated as Resource Description Framework Schema (RDFS)
according to IEC 61970-501:2006 (with some extension) and IEC 61970-501:ED2 when
published.

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SIST EN IEC 61970-452:2022(Main)
Energy management system application program interface (EMS-API) - Part 452: CIM static transmission network model profiles
EN IEC 61970-452:2021

This document is one of the IEC 61970-450 to 499 series that, taken as a whole, defines at an abstract level the content and exchange mechanisms used for data transmitted between control centres and/or control centre components, such as power systems applications.
The purpose of this document is to define the subset of classes, class attributes, and roles from the CIM necessary to execute state estimation and power flow applications. The North American Electric Reliability Council (NERC) Data Exchange Working Group (DEWG) Common Power System Modelling group (CPSM) produced the original data requirements, which are shown in Annex E. These requirements are based on prior industry practices for exchanging power system model data for use primarily in planning studies. However, the list of required data has been extended starting with the first edition of this standard to facilitate a model exchange that includes parameters common to breaker-oriented applications. Where necessary this document establishes conventions, shown in Clause 6, with which an XML data file must comply in order to be considered valid for exchange of models.
This document is intended for two distinct audiences, data producers and data recipients, and may be read from two perspectives.
From the standpoint of model export software used by a data producer, the document describes a minimum subset of CIM classes, attributes, and associations which must be present in an XML formatted data file for model exchange. This standard does not dictate how the network is modelled, however. It only dictates what classes, attributes, and associations are to be used to describe the source model as it exists.

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SIST EN IEC 61970-600-1:2021(Main)
Energy management system application program interface (EMS-API) - Part 600-1: Common Grid Model Exchange Specification (CGMES) - Structure and rules
EN IEC 61970-600-1:2021

This part of IEC 61970, which covers the definition of Common Grid Model Exchange Standard
(CGMES), defines the main rules and application’s requirements to meet business requirements
for assembled and merged model to fit relevant business services. This document does not
define the business requirements, business processes nor how applications are implemented.
This document defines how relevant Common Information Model (CIM) standards work together
so that specific business requirements can be resolved.
It also includes extensions to the Common Information Model (CIM). The current extensions are
defined in IEC 61970-301:2020 and will be covered in its future Amendment 1, but additional
extensions can be defined in other standards in the IEC 61970-600-series. The extensions can
be used to define additional profiles or to expand IEC 61970-450-series or IEC 61968-13
profiles. However, primary CGMES includes additional constraints on existing profiles and
validation of assembled and merged models that is based on existing profiles. This can be done
by making optional attributes and associations mandatory (required).
In addition, this document includes the specification of the serialisation that must be supported
by referring to an existing standard defined in IEC 61970-550-series, e.g., IEC 61970-552, and
making relevant constraints related to it.
The goal is to achieve interoperability between applications using CGMES in a highperformance
environment with combined minimum effort so that relevant business processes
are satisfied.
An overview of IEC 61970-600 series is provided in the following table, which also presents
identified needs that are not yet addressed.

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SIST EN IEC 61968-3:2021(Main)
Application integration at electric utilities - System interfaces for distribution management - Part 3: Interface for network operations
EN IEC 61968-3:2021

Per the IEC 61968 Interface Reference Model, the Network Operations function defined in this part of IEC 61968 provides utilities the means to supervise main substation topology (breaker and switch state), feeder topology and control equipment status through SCADA, AMI and other data sources. It also provides the means for handling network connectivity and loading conditions. Finally, it makes it possible for utilities to locate customer telephone complaints and coordinate activities of field crews with respect to planned and unplanned outages.
IEC 61968-3 specifies the information content of a set of message payloads that can be used to support many of the business functions related to network operations. Typical uses of the message payloads defined in IEC 61968-3 include data acquisition by external systems, fault isolation, fault restoration, trouble management and coordination of the real-time state of the network.
The scope diagram shown in [Figure 1] illustrates the possibility of implementing IEC 61968-3 functionality 51 as either a single integrated advanced distribution management system or as a set of separate functions - OMS, DMS and SCADA. Utilities may chose to buy these systems from different vendors and integrate them using the IEC 61968-3 messages. Alternatively, a single vendor could provide two or all of these components as a single integrated system. In the case of more than one system being provided by the same vendor, the vendor may chose to use either extensions of the IEC 61968- messages or a proprietary integration mechanism to provide enhanced functionality over and above what is required/supported by the IEC 61968-3 specification. While this is a possible implementation, clause 4.3 defines the scope in terms of business functions that are implemented in common vendor offerings.
Annexes in this standard document integration scenarios or use cases, which are informative examples showing typical ways of using the message payloads defined in this document as well as message payloads to be defined in other parts of the IEC 61968 series.

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SIST EN IEC 61970-457:2021(Main)
Energy Management System Application Program Interface (EMS-API) – Part 457: Dynamics profile
EN IEC 61970-457:2021

This part of IEC 61970 specifies a standard interface for exchanging dynamic model information
needed to support the analysis of the steady state stability (small-signal stability) and/or
transient stability of a power system or parts of it. The schema(s) for expressing the dynamic
model information are derived directly from the CIM, more specifically from IEC 61970-302.
The scope of this document includes only the dynamic model information that needs to be
exchanged as part of a dynamic study, namely the type, description and parameters of each
control equipment associated with a piece of power system equipment included in the steady
state solution of a complete power system network model. Therefore, this profile is dependent
upon other standard profiles for the equipment as specified in IEC 61970-452, CIM static
transmission network model profiles, the topology, the steady state hypothesis and the steadystate
solution (as specified in IEC 61970-456, Solved power system state profiles) of the power
system, which bounds the scope of the exchange. The profile information described by this
document needs to be exchanged in conjunction with IEC 61970-452 and IEC 61970-456
profiles’ information to support the data requirements of transient analysis tools. IEC 61970-456
provides a detailed description of how different profile standards can be combined to form
various types of power system network model exchanges.
This document supports the exchange of the following types of dynamic models:
• standard models: a simplified approach to exchange, where models are contained in
predefined libraries of classes interconnected in a standard manner that represent dynamic
behaviour of elements of the power system. The exchange only indicates the name of the
model along with the attributes needed to describe its behaviour.
• proprietary user-defined models: an exchange that would provide users the ability to
exchange the parameters of a model representing a vendor or user proprietary device where
an explicit description of the model is not described in this document. The connections
between the proprietary models and standard models are the same as described for the
standard models exchange. Recipient of the data exchange will need to contact the sender
for the behavioural details of the model.
This document builds on IEC 61970-302, CIM for dynamics which defines the descriptions of
the standard dynamic models, their function block diagrams, and how they are interconnected
and associated with the static network model. This type of model information is assumed to be
pre-stored by all software applications hence it is not necessary to be exchanged in real-time
or as part of a dynamics model exchange.

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SIST EN IEC 61968-13:2021(Main)
Application integration at electric utilities - System interfaces for distribution management - Part 13: Common distribution power system model profiles
EN IEC 61968-13:2021

This part of IEC 61968 specifies profiles that can be used to exchange Network Models in a
Utility or between a Utility and external applications to the utility. This document provides a list
of profiles which allow to model balanced and unbalanced distribution networks in order to
conduct network analysis (Power flow calculation). Therefore, it leverages already existing
profiles (IEC 61970-45x based on IEC 61970-301 (CIM base) or profiles based on
IEC 6196811
CIM extension for Distribution). This document reuses some profiles without any
change, or eventually extends them or restricts them. Moreover, it proposes other profiles to
reflect Distribution needs.
Use of CIM in Distribution is not a new topic. Several documents can be of interest
[13][17][18][19][20]. This document includes informative parts, as CIM model extensions, which
could be integrated in future versions of the IEC CIM Model. These extensions have been used
by some utilities for utility internal information exchange use cases and to support information
exchanges between different market participants like Transmisstion System Operators (TSO),
Distributed System Operators (DSO), Distributed Network Operators (DNO) and Significant Grid
Users (SGU) including generators and industry (see Annex J for example).

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