iTeh Standards logo
EURUSD
Your shopping cart is empty.
CLC

EN IEC 61970-456:2022

(Main)

Energy management system application program interface (EMS-API) - Part 456: Solved power system state profiles

Energy management system application program interface (EMS-API) - Part 456: Solved power system state profiles

IEC 61970-456:2021 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. This third edition cancels and replaces the second edition published in 2018. This edition constitutes a technical revision. It is based on the IEC 61970 UML version ‘IEC61970CIM17v40’, dated 2020-08-24. This edition includes the following significant technical changes with respect to the previous edition: a) Updated to support CIM17 (IEC 61970-301:2020+AMD1) and align with IEC 61970‑452:ED4. b) The classes PowerElectronicsConnection, PowerElectronicsUnit and PowerElectronicsWindUnit are added to the Steady State Hypothesis (SSH) profile to match the changes done for Edition 4 of IEC 61970-452 , Core Equipment profile. c) Added relevant terms used in this document. d) Clarified use of Equipment.inService and Equipment.normallyInService.

Schnittstelle für Anwendungsprogramme für Netzführungssysteme (EMS-API) – Teil 456: Gelöste Zustandsprofile des Stromversorgungssystems

Interface de programmation d'application pour système de gestion d'énergie (EMS-API) - Partie 456: Profils d'état de réseaux électriques résolus

IEC 61970-456:2021 appartient aux séries IEC 61970-450 à IEC 61970-499 qui, considérées dans leur ensemble, définissent à un niveau abstrait le contenu et les mécanismes d'échange utilisés pour les données transmises entre des applications d’analyses de réseaux électriques, des centres de conduite et/ou des composants de centre de conduite. Le présent document a pour objet de définir de façon rigoureuse le sous-ensemble de classes, les attributs de classe et les rôles du CIM, nécessaires pour décrire le résultat de l'estimation d'état, du calcul de répartition et d'autres applications analogues qui produisent une solution en régime établi d'un réseau électrique dans un ensemble de cas d'utilisation inclus à titre informatif dans le présent document. Le présent document s'adresse à deux destinataires distincts, les producteurs de données et les destinataires de données. Il peut être interprété selon ces deux points de vue. Du point de vue du logiciel d'exportation des modèles utilisé par un producteur de données, le présent document présente la façon dont un producteur peut décrire une instance d'un cas de réseau pour le rendre accessible à un autre programme. Du point de vue du client, le document définit ce que ce logiciel d'importation doit être capable d'interpréter afin de pouvoir absorber les cas de calcul de répartition. Il existe un grand nombre de cas d'utilisation pour lesquels l'utilisation du présent document est prévue et ils diffèrent dans la manière dont le document est appliqué dans chaque cas. Il est prévu que les personnes chargées de la mise en œuvre envisagent les cas d'utilisation qu'ils souhaitent traiter afin de connaître l'étendue des différentes options qu'ils doivent traiter. Par exemple, le profil définit dans le présent document est utilisé dans certains cas pour échanger des conditions initiales plutôt que des conditions résolues, de sorte que s'il s'agit d'un cas d'utilisation important, cela signifie qu’il est nécessaire qu’une application du client soit capable de traiter un état non résolu ainsi qu'un état qui a satisfait à certains critères de solution. Cette troisième édition annule et remplace la deuxième édition parue en 2018. Cette édition constitue une révision technique. Elle est fondée sur la version UML de l’IEC 61970 ʺIEC61970CIM17v40ʺ datée du 2020-08-24. Cette édition inclut les modifications techniques majeures suivantes par rapport à l'édition précédente: a) mise à jour pour prendre en charge le CIM17 (IEC 61970-301:2020+AMD1) et s'aligner sur l'IEC 61970-452:ED4; b) les classes PowerElectronicsConnection, PowerElectronicsUnit et PowerElectronicsWindUnit sont ajoutées au profil SSH (Steady State Hypothesis) pour correspondre aux modifications apportées au profil CoreEquipment de l’édition 4 de l’IEC 61970-452 ; c) ajout des termes pertinents utilisés dans le présent document; d) clarification de l'utilisation de Equipment.inService et de Equipment.normallyInService.

Aplikacijski programski vmesnik za sistem upravljanja z energijo (EMS-API) - 456. del: Profili stanja sproščenega elektroenergetskega sistema

Ta del standarda IEC 61970 pripada skupini standardov od IEC 61970-450 do IEC 61970-499, ki kot celota na abstraktni ravni določa vsebino in mehanizme izmenjave, ki se uporabljajo za podatke, prenesene med aplikacijami za analizo elektroenergetskega sistema, nadzornimi centri in/ali komponentami nadzornih centrov. Namen tega dokumenta je natančna opredelitev podmnožice razredov, atributov razredov in vlog v skupnem informacijskem modelu (CIM), potrebnih za opis rezultata ocenjevanja stanj, pretoka moči in drugih podobnih aplikacij, ki ustvarijo ustaljeno rešitev napajalnega omrežja na podlagi nabora primerov uporabe, ki jih ta standard informativno vključuje. Ta dokument je namenjen dvema ločenima skupinama (proizvajalcem podatkov in prejemnikom podatkov) in se lahko tolmači s teh dveh vidikov. S stališča programske opreme za izvažanje modelov, ki jo uporablja proizvajalec podatkov, dokument določa, kako lahko proizvajalec opiše omrežni primer, da omogoči njegovo razpoložljivost drugemu programu. S stališča porabnika dokument določa, katere zmogljivosti tolmačenja mora vključevati programska oprema za uvažanje, da lahko porablja primere pretoka moči. Obstajajo številni različni primeri uporabe, pri katerih se pričakuje uporaba tega dokumenta in ki se razlikujejo v načinu uporabe dokumenta. Od izvajalcev se pričakuje odločitev, katere primere uporabe želijo zajeti, da določijo obseg različnih možnosti, ki morajo biti vključene. Profili, opredeljeni v tem dokumentu, se na primer uporabijo v nekaterih primerih za izmenjavo začetnih pogojev namesto izpolnjenih pogojev. Če je to pomemben primer uporabe, to pomeni, da mora biti porabniška aplikacija zmožna obravnavati tako neizpolnjeno stanje kot tudi stanje, pri katerem so bili izpolnjeni nekateri kriteriji rešitve.

General Information

Status
Published
Publication Date
10-Feb-2022
ICS
33.200 - Telecontrol. Telemetering
Technical Committee
CLC/TC 57 - Power systems management and associated information exchange
Drafting Committee
IEC/TC 57 - IEC_TC_57
Current Stage
6060 - Document made available - Publishing
Start Date
11-Feb-2022
Due Date
28-Jun-2021
Completion Date
11-Feb-2022
Mandate
M/490 - Standardisation mandate to the European Standardisation Organisations (ESOs) to support European Smart Grid deployment
Ref Project
SIST EN IEC 61970-456:2022 - Energy management system application program interface (EMS-API) - Part 456: Solved power system state profiles

Relations

Replaces
EN IEC 61970-456:2018 - Energy management system application program interface (EMS-API) - Part 456: Solved power system state profiles
Effective Date
15-Feb-2022
EN IEC 61970-456:2022 - BARVEEN IEC 61970-456:2022 - BARVE
PreviousNext
Standard
EN IEC 61970-456:2022 - BARVE
English language
110 pages
sale 10% off
Preview
sale 10% off
Preview
e-Library read for
1 day

Standards Content (Sample)


SLOVENSKI STANDARD
01-maj-2022
Nadomešča:
SIST EN IEC 61970-456:2018
Aplikacijski programski vmesnik za sistem upravljanja z energijo (EMS-API) - 456.
del: Profili stanja sproščenega elektroenergetskega sistema
Energy management system application program interface (EMS-API) - Part 456: Solved
power system state profiles
Schnittstelle für Anwendungsprogramme für Netzführungssysteme (EMS-API) - Teil 456:
Globale Stabilitätsbeurteilung
Interface de programmation d'application pour système de gestion d'énergie (EMS-API) -
Partie 456: Profils d'état de réseaux électriques résolus
Ta slovenski standard je istoveten z: EN IEC 61970-456:2022
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
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

EUROPEAN STANDARD EN IEC 61970-456

NORME EUROPÉENNE
EUROPÄISCHE NORM February 2022
ICS 33.200 Supersedes EN IEC 61970-456:2018 and all of its
amendments and corrigenda (if any)
English Version
Energy management system application program interface
(EMS-API) - Part 456: Solved power system state profiles
(IEC 61970-456:2021)
Interface de programmation d'application pour système de Schnittstelle für Anwendungsprogramme für
gestion d'énergie (EMS-API) - Partie 456: Profils d'état de Netzführungssysteme (EMS-API) - Teil 456: Gelöste
réseaux électriques résolus Zustandsprofile des Stromversorgungssystems
(IEC 61970-456:2021) (IEC 61970-456:2021)
This European Standard was approved by CENELEC on 2022-01-19. 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, France, Germany, Greece, Hungary, Iceland, Ireland, Italy, Latvia, Lithuania, Luxembourg, Malta, the
Netherlands, Norway, Poland, Portugal, Republic of North Macedonia, Romania, Serbia, 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: Rue de la Science 23, B-1040 Brussels
© 2022 CENELEC All rights of exploitation in any form and by any means reserved worldwide for CENELEC Members.
Ref. No. EN IEC 61970-456:2022 E

European foreword
The text of document 57/2406/FDIS, future edition 3 of IEC 61970-456, 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 IEC 61970-456:2022.
The following dates are fixed:
• latest date by which the document has to be implemented at national (dop) 2022-10-19
level by publication of an identical national standard or by endorsement
• latest date by which the national standards conflicting with the (dow) 2025-01-19
document have to be withdrawn
This document supersedes EN IEC 61970-456:2018 and all of its amendments and corrigenda (if
any).
Attention is drawn to the possibility that some of the elements of this document may be the subject of
patent rights. CENELEC shall not be held responsible for identifying any or all such patent rights.
This document has been prepared under a Standardization Request given to CENELEC by the
European Commission and the European Free Trade Association.
Any feedback and questions on this document should be directed to the users’ national committee. A
complete listing of these bodies can be found on the CENELEC website.
Endorsement notice
The text of the International Standard IEC 61970-456:2021 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 61970-1 NOTE Harmonized as EN 61970-1
IEC/TS 61970-2 NOTE Harmonized as CLC/TS 61970-2
IEC 61970-453 NOTE Harmonized as EN 61970-453
IEC 61970-501 NOTE Harmonized as EN 61970-501
IEC 61970-552 NOTE Harmonized as EN 61970-552
IEC 61970-600-1 NOTE Harmonized as EN IEC 61970-600-1
IEC 61970-600-2 NOTE Harmonized as EN IEC 61970-600-2
Annex ZA
(normative)
Normative references to international publications
with their corresponding European publications
The following documents are referred to in the text in such a way that some or all of their content
constitutes requirements of this document. For dated references, only the edition cited applies. For
undated references, the latest edition of the referenced document (including any amendments)
applies.
NOTE 1 Where an International Publication has been modified by common modifications, indicated by (mod), the
relevant EN/HD applies.
NOTE 2 Up-to-date information on the latest versions of the European Standards listed in this annex is available
here: www.cenelec.eu.
Publication Year Title EN/HD Year
IEC 61970-301 2020 Energy management system application EN IEC 61970-301 2020
program interface (EMS-API) - Part 301:
Common information model (CIM) base
1 2
A1 — A1 —
IEC 61970-452 2021 Energy management system application EN IEC 61970-452 2021
program interface (EMS-API) - Part 452:
CIM static transmission network model
profiles
Under preparation. Stage at the time of publication: IEC/RPVC 61970-301/AMD1:2021.
Under preparation. Stage at the time of publication: EN IEC 61970-301:2020/FprA1:2021.
IEC 61970-456 ®
Edition 3.0 2021-12
INTERNATIONAL
STANDARD
NORME
INTERNATIONALE
colour
inside
Energy management system application program interface (EMS-API) –

Part 456: Solved power system state profiles

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

(EMS-API) –
Partie 456: Profils d'état de réseaux électriques résolus

INTERNATIONAL
ELECTROTECHNICAL
COMMISSION
COMMISSION
ELECTROTECHNIQUE
INTERNATIONALE
ICS 33.200 ISBN 978-2-8322-1046-1

– 2 – IEC 61970-456:2021 © IEC 2021
CONTENTS
FOREWORD . 10
INTRODUCTION . 12
1 Scope . 13
2 Normative references . 13
3 Terms and definitions . 13
4 Profile specification . 15
4.1 General . 15
4.1.1 General . 15
4.1.2 Steady state hypothesis profile . 15
4.1.3 Topology profile . 16
4.1.4 State variables profile . 16
4.2 Requirements and constraints . 16
5 Overview . 21
5.1 General . 21
5.2 Modelling authorities . 22
5.3 Profile relationships . 24
5.4 Connectivity model. 25
6 Use cases . 26
6.1 Overview. 26
6.2 EMS network analysis integration . 28
6.3 Power flow based network analysis . 28
6.4 Model partitioning and boundary modelling . 29
6.4.1 General . 29
6.4.2 Network model boundaries . 30
6.4.3 Network parts and model merge . 31
6.4.4 Partitioning of a merged model . 33
7 Data model with CIMXML examples . 34
7.1 Topology processing . 34
7.1.1 Overview . 34
7.1.2 Bus-branch and node-breaker models . 34
8 Detailed Profile specification . 36
8.1 General . 36
8.2 Package SteadyStateHypothesisProfile. 36
8.2.1 General . 36
8.2.2 (abstract) ACDCConverter . 41
8.2.3 (Description) ACDCConverterDCTerminal . 41
8.2.4 (abstract) ACDCTerminal . 42
8.2.5 (Description) ActivePowerLimit . 42
8.2.6 (Description) ApparentPowerLimit . 42
8.2.7 (Description) AsynchronousMachine . 43
8.2.8 (Description) BatteryUnit. 43
8.2.9 (Description) Breaker . 43
8.2.10 (abstract) ConductingEquipment . 44
8.2.11 (Description) ConformLoad . 44
8.2.12 (Description) ControlArea . 44
8.2.13 (Description) CsConverter . 45

IEC 61970-456:2021 © IEC 2021 – 3 –
8.2.14 (Description) CurrentLimit . 46
8.2.15 (abstract) DCBaseTerminal . 47
8.2.16 (Description) DCTerminal . 47
8.2.17 (Description) Disconnector. 47
8.2.18 (Description) DisconnectingCircuitBreaker . 48
8.2.19 (abstract) EnergyConnection . 48
8.2.20 (Description) EnergyConsumer . 48
8.2.21 (Description) EnergySource . 49
8.2.22 Equipment . 50
8.2.23 (abstract) EquivalentEquipment . 50
8.2.24 (Description) EquivalentInjection . 50
8.2.25 (Description) ExternalNetworkInjection . 51
8.2.26 (Description) Fuse . 51
8.2.27 (Description) GeneratingUnit . 52
8.2.28 (Description) GroundDisconnector . 52
8.2.29 (Description) HydroGeneratingUnit . 53
8.2.30 (abstract) IdentifiedObject root class . 53
8.2.31 (Description) Jumper . 53
8.2.32 (Description) LinearShuntCompensator . 54
8.2.33 (Description) LoadBreakSwitch . 54
8.2.34 (Description) NonConformLoad . 54
8.2.35 (Description) NonlinearShuntCompensator . 55
8.2.36 (Description) NuclearGeneratingUnit . 55
8.2.37 (abstract) OperationalLimit . 55
8.2.38 (abstract) PhaseTapChanger . 56
8.2.39 (Description) PhaseTapChangerAsymmetrical . 56
8.2.40 (Description) PhaseTapChangerLinear . 57
8.2.41 (abstract) PhaseTapChangerNonLinear . 57
8.2.42 (Description) PhaseTapChangerSymmetrical . 57
8.2.43 (Description) PhaseTapChangerTabular . 58
8.2.44 (Description) PowerElectronicsConnection . 58
8.2.45 (abstract) PowerElectronicsUnit . 59
8.2.46 (abstract) PowerSystemResource . 59
8.2.47 (abstract) ProtectedSwitch . 59
8.2.48 (Description) RatioTapChanger . 60
8.2.49 (abstract,Description) RegulatingCondEq . 60
8.2.50 (Description) RegulatingControl . 60
8.2.51 (abstract) RotatingMachine . 61
8.2.52 (abstract) ShuntCompensator . 62
8.2.53 (Description) SolarGeneratingUnit . 63
8.2.54 (Description) StaticVarCompensator . 63
8.2.55 (Description) StationSupply . 63
8.2.56 (Description) Switch . 64
8.2.57 (Description) SynchronousMachine . 64
8.2.58 (abstract) TapChanger . 65
8.2.59 (Description) TapChangerControl . 65
8.2.60 (Description) Terminal . 66
8.2.61 (Description) ThermalGeneratingUnit . 66
8.2.62 (Description) VoltageLimit . 66

– 4 – IEC 61970-456:2021 © IEC 2021
8.2.63 (Description) VsConverter . 67
8.2.64 (Description) WindGeneratingUnit . 68
8.2.65 AsynchronousMachineKind enumeration . 68
8.2.66 BatteryStateKind enumeration . 68
8.2.67 CsOperatingModeKind enumeration. 68
8.2.68 CsPpccControlKind enumeration . 69
8.2.69 SynchronousMachineOperatingMode enumeration . 69
8.2.70 UnitMultiplier enumeration . 69
8.2.71 UnitSymbol enumeration . 70
8.2.72 VsPpccControlKind enumeration . 76
8.2.73 VsQpccControlKind enumeration . 76
8.2.74 ActivePower datatype . 77
8.2.75 AngleDegrees datatype . 77
8.2.76 AngleRadians datatype . 77
8.2.77 ApparentPower datatype. 78
8.2.78 CurrentFlow datatype . 78
8.2.79 PerCent datatype . 78
8.2.80 PU datatype . 79
8.2.81 ReactivePower datatype . 79
8.2.82 RealEnergy datatype . 79
8.2.83 Resistance datatype . 79
8.2.84 Voltage datatype. 80
8.2.85 Boolean primitive . 80
8.2.86 Date primitive . 80
8.2.87 Float primitive . 80
8.2.88 Integer primitive . 80
8.2.89 String primitive . 80
8.3 Package TopologyProfile . 80
8.3.1 General . 80
8.3.2 (Description) ACDCConverterDCTerminal . 82
8.3.3 (abstract) ACDCTerminal . 82
8.3.4 (abstract) BaseVoltage root class . 82
8.3.5 (Description) ConnectivityNode root class . 82
8.3.6 (abstract) ConnectivityNodeContainer root class . 83
8.3.7 (abstract) DCBaseTerminal . 83
8.3.8 (abstract) DCEquipmentContainer root class . 83
8.3.9 (Description) DCNode . 83
8.3.10 (Description) DCTerminal . 84
8.3.11 DCTopologicalNode . 84
8.3.12 (abstract) IdentifiedObject root class . 85
8.3.13 (Description) Terminal . 85
8.3.14 TopologicalNode . 86
8.3.15 Date primitive . 87
8.3.16 (abstract) ReportingGroup . 87
8.3.17 String primitive . 87
8.4 Package StateVariablesProfile . 87
8.4.1 General . 87
8.4.2 (abstract) ACDCConverter . 90
8.4.3 (abstract) ACDCTerminal . 90

IEC 61970-456:2021 © IEC 2021 – 5 –
8.4.4 (Description) CsConverter . 90
8.4.5 (abstract) ConductingEquipment root class . 91
8.4.6 DCTopologicalIsland . 91
8.4.7 (abstract) DCTopologicalNode . 92
8.4.8 (abstract) IdentifiedObject root class . 92
8.4.9 (abstract) ShuntCompensator root class . 93
8.4.10 SvInjection root class. 93
8.4.11 SvPowerFlow root class . 93
8.4.12 SvShuntCompensatorSections root class . 94
8.4.13 SvStatus root class . 94
8.4.14 SvSwitch root class . 95
8.4.15 SvTapStep root class . 95
8.4.16 SvVoltage root class . 96
8.4.17 (abstract) Switch . 96
8.4.18 (abstract) TapChanger root class . 96
8.4.19 (abstract) Terminal . 97
8.4.20 TopologicalIsland. 97
8.4.21 (abstract) TopologicalNode root class . 98
8.4.22 (Description) VsConverter . 98
8.4.23 UnitMultiplier enumeration . 98
8.4.24 UnitSymbol enumeration . 99
8.4.25 ActivePower datatype . 105
8.4.26 AngleDegrees datatype . 105
8.4.27 CurrentFlow datatype . 105
8.4.28 ReactivePower datatype . 105
8.4.29 Voltage datatype. 106
8.4.30 Boolean primitive . 106
8.4.31 Date primitive . 106
8.4.32 Float primitive . 106
8.4.33 String primitive . 106
Bibliography . 107

Figure 1 – Relations between MAS, profile and dataset . 23
Figure 2 – Profile relationships . 24
Figure 3 – Connectivity and solution model . 25
Figure 4 – The European power system with regions . 27
Figure 5 – Information exchange in power flow and sharing of results . 27
Figure 6 – EMS datasets to an external client . 28
Figure 7 – Node-breaker power flow integration architecture . 29
Figure 8 – Bus-branch power flow integration architecture . 29
Figure 9 – Line boundary dataset example . 30
Figure 10 – Substation boundary dataset example . 30
Figure 11 – Merged model . 31
Figure 12 – Alternate boundary modelling . 32
Figure 13 – Merged model alternatives . 32
Figure 14 – Partitioning of a merged model . 33
Figure 15 – Relation between ConnectivityNode and TopologicalNode . 35

– 6 – IEC 61970-456:2021 © IEC 2021
Figure 16 – Bus-branch modelling of bus coupler and line transfer . 36
Figure 17 – Class diagram
SteadyStateHypothesisProfile::SteadyStateHypothesisProfile . 37
Figure 18 – Class diagram SteadyStateHypothesisProfile::Core. 38
Figure 19 – Class diagram SteadyStateHypothesisProfile::DC . 39
Figure 20 – Class diagram SteadyStateHypothesisProfile::OperationalLimits . 39
Figure 21 – Class diagram SteadyStateHypothesisProfile::Datatypes . 40
Figure 22 – Class diagram TopologyProfile::TopologyProfile . 81
Figure 23 – Class diagram TopologyProfile::Datatypes . 81
Figure 24 – Class diagram StateVariablesProfile::StateVariablesProfile . 88
Figure 25 – Class diagram StateVariablesProfile::Datatypes . 89

Table 1 – Attributels of SteadyStateHypothesisProfile::ACDCConverter . 41
Table 2 – Attributes of SteadyStateHypothesisProfile::ACDCConverterDCTerminal . 42
Table 3 – Attributes of SteadyStateHypothesisProfile::ACDCTerminal . 42
Table 4 – Attributes of SteadyStateHypothesisProfile::ActivePowerLimit . 42
Table 5 – Attributes of SteadyStateHypothesisProfile::ApparentPowerLimit . 43
Table 6 – Attributes of SteadyStateHypothesisProfile::AsynchronousMachine . 43
Table 7 – Attributes of SteadyStateHypothesisProfile::BatteryUnit . 43
Table 8 – Attributes of SteadyStateHypothesisProfile::Breaker . 44
Table 9 – Attributes of SteadyStateHypothesisProfile::ConductingEquipment. 44
Table 10 – Attributes of SteadyStateHypothesisProfile::ConformLoad . 44
Table 11 – Attributes of SteadyStateHypothesisProfile::ControlArea . 45
Table 12 – Attributes of SteadyStateHypothesisProfile::CsConverter . 46
Table 13 – Attributes of SteadyStateHypothesisProfile::CurrentLimit . 46
Table 14 – Attributes of SteadyStateHypothesisProfile::DCBaseTerminal . 47
Table 15 – Attributes of SteadyStateHypothesisProfile::DCTerminal . 47
Table 16 – Attributes of SteadyStateHypothesisProfile::Disconnector . 47
Table 17 – Attributes of SteadyStateHypothesisProfile::DisconnectingCircuitBreaker . 48
Table 18 – Attributes of SteadyStateHypothesisProfile::EnergyConnection . 48
Table 19 – Attributes of SteadyStateHypothesisProfile::EnergyConsumer . 49
Table 20 – Attributes of SteadyStateHypothesisProfile::EnergySource . 49
Table 21 – Attributes of SteadyStateHypothesisProfile::Equipment . 50
Table 22 – Attributes of SteadyStateHypothesisProfile::EquivalentEquipment . 50
Table 23 – Attributes of SteadyStateHypothesisProfile::EquivalentInjection . 51
Table 24 – Attributes of SteadyStateHypothesisProfile::ExternalNetworkInjection . 51
Table 25 – Attributes of SteadyStateHypothesisProfile::Fuse . 52
Table 26 – Attributes of SteadyStateHypothesisProfile::GeneratingUnit . 52
Table 27 – Attributes of SteadyStateHypothesisProfile::GroundDisconnector . 52
Table 28 – Attributes of SteadyStateHypothesisProfile::HydroGeneratingUnit . 53
Table 29 – Attributes of SteadyStateHypothesisProfile::IdentifiedObject . 53
Table 30 – Attributes of SteadyStateHypothesisProfile::Jumper . 53
Table 31 – Attributes of SteadyStateHypothesisProfile::LinearShuntCompensator . 54

IEC 61970-456:2021 © IEC 2021 – 7 –
Table 32 – Attributes of SteadyStateHypothesisProfile::LoadBreakSwitch . 54
Table 33 – Attributes of SteadyStateHypothesisProfile::NonConformLoad . 55
Table 34 – Attributes of SteadyStateHypothesisProfile::NonlinearShuntCompensator . 55
Table 35 – Attributes of SteadyStateHypothesisProfile::NuclearGeneratingUnit . 55
Table 36 – Attributes of SteadyStateHypothesisProfile::OperationalLimit . 56
Table 37 – Attributes of SteadyStateHypothesisProfile::PhaseTapChanger . 56
Table 38 – Attributes of
SteadyStateHypothesisProfile::PhaseTapChangerAsymmetrical . 56
Table 39 – Attributes of SteadyStateHypothesisProfile::PhaseTapChangerLinear . 57
Table 40 – Attributes of SteadyStateHypothesisProfile::PhaseTapChangerNonLinear . 57
Table 41 – Attributes of SteadyStateHypothesisProfile::PhaseTapChangerSymmetrical . 58
Table 42 – Attributes of SteadyStateHypothesisProfile::PhaseTapChangerTabular . 58
Table 43 – Attributes of SteadyStateHypothesisProfile::PowerElectronicsConnection . 58
Table 44 – Attributes of SteadyStateHypothesisProfile::PowerElectronicsUnit . 59
Table 45 – Attributes of SteadyStateHypothesisProfile::PowerSystemResource . 59
Table 46 – Attributes of SteadyStateHypothesisProfile::ProtectedSwitch . 59
Table 47 – Attributes of SteadyStateHypothesisProfile::RatioTapChanger . 60
Table 48 – Attributes of SteadyStateHypothesisProfile::RegulatingCondEq . 60
Table 49 – Attributes of SteadyStateHypothesisProfile::RegulatingControl . 61
Table 50 – Attributes of SteadyStateHypothesisProfile::RotatingMachine . 62
Table 51 – Attributes of SteadyStateHypothesisProfile::ShuntCompensator . 62
Table 52 – Attributes of SteadyStateHypothesisProfile::SolarGeneratingUnit . 63
Table 53 – Attributes of SteadyStateHypothesisProfile::StaticVarCompensator . 63
Table 54 – Attributes of SteadyStateHypothesisProfile::StationSupply . 64
Table 55 – Attributes of SteadyStateHypothesisProfile::Switch . 64
Table 56 – Attributes of SteadyStateHypothesisProfile::SynchronousMachine . 65
Table 57 – Attributes of SteadyStateHypothesisProfile::TapChanger . 65
Table 58 – Attributes of SteadyStateHypothesisProfile::TapChangerControl . 66
Table 59 – Attributes of SteadyStateHypothesisProfile::Terminal . 66
Table 60 – Attributes of SteadyStateHypothesisProfile::ThermalGeneratingUnit . 66
Table 61 – Attributes of SteadyStateHypothesisProfile::VoltageLimit . 67
Table 62 – Attributes of SteadyStateHypothesisProfile::VsConverter . 67
Table 63 – Attributes of SteadyStateHypothesisProfile::WindGeneratingUnit . 68
Table 64 – Literals of SteadyStateHypothesisProfile::AsynchronousMachineKind . 68
Table 65 – Literals of SteadyStateHypothesisProfile::BatteryStateKind . 68
Table 66 – Literals of SteadyStateHypothesisProfile::CsOperatingModeKind . 69
Table 67 – Literals of SteadyStateHypothesisProfile::CsPpccControlKind . 69
Table 68 – Literals of
SteadyStateHypothesisProfile::SynchronousMachineOperatingMode . 69
Table 69 – Literals of SteadyStateHypothesisProfile::UnitMultiplier . 70
Table 70 – Literals of SteadyStateHypothesisProfile::UnitSymbol . 71
Table 71 – Literals of SteadyStateHypothesisProfile::VsPpccControlKind . 76
Table 72 – Literals of SteadyStateHypothesisProfile::VsQpccControlKind . 77
Table 73 – Attributes of SteadyStateHypothesisProfile::ActivePower . 77

– 8 – IEC 61970-456:2021 © IEC 2021
Table 74 – Attributes of SteadyStateHypothesisProfile::AngleDegrees . 77
Table 75 – Attributes of SteadyStateHypothesisProfile::AngleRadians . 78
Table 76 – Attributes of SteadyStateHypothesisProfile::ApparentPower . 78
Table 77 – Attributes of SteadyStateHypothesisProfile::CurrentFlow . 78
Table 78 – Attributes of SteadyStateHypothesisProfile::PerCent . 78
Table 79 – Attributes of SteadyStateHypothesisProfile::PU . 79
Table 80 – Attributes of SteadyStateHypothesisProfile::ReactivePower . 79
Table 81 – Attributes of SteadyStateHypothesisProfile::RealEnergy . 79
Table 82 – Attributes of SteadyStateHypothesisProfile::Resistance . 80
Table 83 – Attributes of SteadyStateHypothesisProfile::Voltage . 80
Table 84 – Attributes of TopologyProfile::ACDCConverterDCTerminal . 82
Table 85 – Association ends of TopologyProfile::ACDCConverterDCTerminal with other
classes . 82
Table 86 – Attributes of TopologyProfile::ACDCTerminal . 82
Table 87 – Association ends of TopologyProfile::ConnectivityNode with other classes . 83
Table 88 – Attributes of TopologyProfile::DCBaseTerminal . 83
Table 89 – Association ends of TopologyProfile::DCBaseTerminal with other classes . 83
Table 90 – Attributes of TopologyProfile::DCNode . 84
Table 91 – Association ends of TopologyProfile::DCNode with other classes . 84
Table 92 – Attributes of TopologyProfile::DCTerminal . 84
Table 93 – Association ends of TopologyProfile::DCTerminal with other classes . 84
Table 94 – Attributes of TopologyProfile::DCTopologicalNode. 85
Table 95 – Association ends of TopologyProfile::DCTopologicalNode with other

classes . 85
Table 96 – Attributes of TopologyProfile::IdentifiedObject . 85
Table 97 – Attributes of TopologyProfile::Terminal . 86
Table 98 – Association ends of TopologyProfile::Terminal with other classes . 86
Table 99 – Attributes of TopologyProfile::TopologicalNode . 86
Table 100 – Association ends of TopologyProfile::TopologicalNode with other classes . 87
Table 101 – Attributes of TopologyProfile::ReportingGroup . 87
Table 102 – Attributes of StateVariablesProfile::ACDCConverter . 90
Table 103 – Attributes of StateVariablesProfile::ACDCTerminal . 90
Table 104 – Attributes of StateVariablesProfile::CsConverter . 91
Table 105 – Attributes of StateVariablesProfile::DCTopologicalIsland . 92
Table 106 – Association ends of StateVariablesProfile::DCTopologicalIsland with other
classes . 92
Table 107 – Attributes of StateVariablesProfile::DCTopologicalNode . 92
Table 108 – Attributes of StateVariablesProfile::IdentifiedObject . 93
Table 109 – Attributes of StateVariablesProfile::SvInjection . 93
Table 110 – Association ends of StateVariablesProfile::SvInjection with other classes . 93
Table 111 – Attributes of StateVariablesProfile::SvPowerFlow . 94
Table 112 – Association ends of StateVariablesProfile::SvPowerFlow with other
classes . 94
Table 113 – Attributes of StateVariablesProfile::SvShuntCompensatorSections . 94

IEC 61970-456:2021 © IEC 2021 – 9 –
Table 114 – Association ends of StateVariablesProfile::SvShuntCompensatorSections
with other classes . 94
Table 115 – Attributes of StateVariablesProfile::SvStatus . 95
Table 116 – Association ends of StateVariablesProfile::SvStatus with oth
...

Questions, Comments and Discussion

Ask us and Technical Secretary will try to provide an answer. You can facilitate discussion about the standard in here.

Loading comments...

This May Also Interest You

CLC
EN IEC 62488-1:2025(Main)
Power line communication systems for power utility applications - Part 1: Planning of analogue and digital power line carrier systems operating over HV electricity grids
SIST EN IEC 62488-1:2025

IEC 62488-1:2025 applies to the planning of analogue (APLC), digital (DPLC) and hybrid analogue-digital (ADPLC) power line carrier communication systems operating over HV electric power networks. The object of this document is to establish the planning of the services and performance parameters for the operational requirements to transmit and receive data efficiently and reliably. Such analogue and digital power line carrier systems are used by the different electricity supply industries and integrated into their communication infrastructure using common communication technologies such as radio links, fibre optic and satellite networks This second edition cancels and replaces the first edition published in 2012. This edition constitutes a technical revision. This edition includes the following significant technical changes with respect to the previous edition: a) Complete revision of this edition with respect to the previous edition with the main focus on planning of analogue and digital power line carrier systems operating over HV power networks; b) A general structure of a bidirectional point-to-multipoint APLC, DPLC or ADPLC link has been introduced; c) Introduction of a new approach for global frequency planning.

  • Standard
    108 pages
    English language
    sale 10% off
    e-Library read for
    1 day
CLC
EN 61850-10:2013/A1:2025(Amendment)
Communication networks and systems for power utility automation - Part 10: Conformance testing
SIST EN 61850-10:2013/A1:2025
  • Amendment
    76 pages
    English language
    sale 10% off
    e-Library read for
    1 day
CLC
EN IEC 62746-4:2025(Main)
Systems interface between customer energy management system and the power management system - Part 4: Demand Side Resource Interface
SIST EN IEC 62746-4:2025

IEC 62746-4:2024 describes CIM profiles for Demand-Side Resource Interface and is based on the use case shown in Annex A of this document. Schemas associated with this document were generated using the CIM101 UML and leverages the Market package. This document defines profiles complimentary to other standards, namely those in IEC 61970, IEC 61968, and IEC 62325.

  • Standard
    76 pages
    English language
    sale 10% off
    e-Library read for
    1 day
CLC
EN 61850-6:2010/A2:2025(Amendment)
Communication networks and systems for power utility automation - Part 6: Configuration description language for communication in power utility automation systems related to IEDs
SIST EN 61850-6:2010/A2:2025
  • Amendment
    94 pages
    English language
    sale 10% off
    e-Library read for
    1 day
CLC
EN IEC 61968-9:2024(Main)
Enterprise business function interfaces for utility operations - Part 9: Interfaces for meter reading and control
SIST EN IEC 61968-9:2024

IEC 61968-9:2024 specifies the information content of a set of message types that can be used to support many of the business functions related to meter reading and control. Typical uses of the message types include meter reading, controls, events, customer data synchronization and customer switching. Although intended primarily for electrical distribution networks, IEC 61968-9 can be used for other metering applications, including non-electrical metered quantities necessary to support gas and water networks. The purpose of this document is to define a standard for the integration of metering systems (MS), which includes traditional manual systems, and (one or two-way) automated meter reading (AMR) systems, and meter data management (MDM) systems with other enterprise systems and business functions within the scope of IEC 61968. The scope of this document is the exchange of information between metering systems, MDM systems and other systems within the utility enterprise. The specific details of communication protocols those systems employ are outside the scope of this document. Instead, this document will recognize and model the general capabilities that can be potentially provided by advanced and/or legacy meter infrastructures, including two-way communication capabilities such as load control, dynamic pricing, outage detection, distributed energy resource (DER) control signals and on-request read. In this way, this document will not be impacted by the specification, development and/or deployment of next generation meter infrastructures either through the use of standards or proprietary means. The focus of IEC 61968-9 is to define standard messages for the integration of enterprise applications, these messages may be directly or indirectly related to information flows within a broader scope. Examples would include messaging between head end systems and meters or PAN devices. The various components described later in this document will typically fall into either the category of a metering system (MS) head end, an MDM or other enterprise application (e.g. OMS, DRMS, CIS). The capabilities and information provided by a meter reading and meter data management systems are important for a variety of purposes, including (but not limited to) interval data, time-based demand data, time-based energy data (usage and production), outage management, service interruption, service restoration, quality of service monitoring, distribution network analysis, distribution planning, demand response, customer billing and work management. This standard also extends the CIM (Common Information Model) to support the exchange of meter data. This third edition cancels and replaces the second edition published in 2013. This edition constitutes a technical revision. Please see the foreword of IEC 61968-9 for further details.

  • Standard
    359 pages
    English language
    sale 10% off
    e-Library read for
    1 day
CLC
EN IEC 61970-457:2024(Main)
Energy management system application program interface (EMS-API) - Part 457: Dynamics profile
SIST EN IEC 61970-457:2024

IEC 61970-457:2024 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 steady state 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. This second edition cancels and replaces the first edition published in 2021. This edition constitutes a technical revision. This edition includes the following significant technical changes with respect to the previous edition: a) The majority of issues detected in IEC 61970-302:2018 and fixed in IEC 61970-302:2022 led to update of this document; b) IEEE 421.5-2016 on Excitation systems is fully covered; c) IEEE turbine report from 2013 was considered and as a result a number of gas, steam and hydro turbines/governors are added; d) IEC 61400-27-1:2020 on wind turbines is fully incorporated; e) WECC Inverter-Based Resource (IBR) models, Hybrid STATCOM models and storage models are added; f) The user defined models approach was enhanced in IEC 61970-302:2022 adding a model which enables modelling of a detailed dynamic model. This results in the creation of two additional pr

  • Standard
    780 pages
    English language
    sale 10% off
    e-Library read for
    1 day
CLC
EN IEC 61970-302:2024(Main)
Energy management system application program interface (EMS-API) - Part 302: Common information model (CIM) dynamics
SIST EN IEC 61970-302:2024

IEC 61970-302:2024 specifies a Dynamics package which contains part of the CIM to support the exchange of models between software applications that perform analysis of the steady-state stability (small-signal stability) or transient stability of a power system as defined by IEEE / CIGRE, Definition and classification of power system stability IEEE/CIGRE joint task force on stability terms and definitions. The model descriptions in this document provide specifications for each type of dynamic model as well as the information that needs to be included in dynamic case exchanges between planning/study applications. The scope of the CIM Dynamics package specified in this document includes: • standard models: a simplified approach to describing dynamic models, where models representing dynamic behaviour of elements of the power system are contained in predefined libraries of classes which are interconnected in a standard manner. Only the names of the selected elements of the models along with their attributes are needed to describe dynamic behaviour. • proprietary user-defined models: an approach providing users the ability to define the parameters of a dynamic behaviour model representing a vendor or user proprietary device where an explicit description of the model is not provided by this document. The same libraries and standard interconnections are used for both proprietary user-defined models and standard models. The behavioural details of the model are not documented in this document, only the model parameters. • A model to enable exchange of models’ descriptions. This approach can be used to describe user defined and standard models. • A model to enable exchange of simulation results. This second edition cancels and replaces the first edition published in 2018. This edition constitutes a technical revision. This edition includes the following significant technical changes with respect to the previous edition: a) The majority of issues detected in IEC 61970-302:2018 are addressed; b) IEEE 421.5-2016 on Excitation systems is fully covered; c) The IEEE turbine report from 2013 was considered and as a result a number of gas, steam and hydro turbines/governors are added; d) IEC 61400-27-1:2020 on wind turbines is fully incorporated; e) WECC Inverter-Based Resource (IBR) models, Hybrid STATCOM models and storage models are added; f) The user defined models are enhanced with a model which enables modelling of detailed dynamic model; g) A model to enable exchange of simulation results is added; h) The work on the HVDC models is not complete. The HVDC dynamics models are a complex domain in which there are no models that are approved or widely recognised on international level, i.e. there are only project-based models. At this stage IEC 61970-302:2022 only specifies some general classes. However, it is recognised that better coverage of HVDC will require a further edition of this document; i) Models from IEEE 1547-2018 "IEEE Standard for Interconnection and Interoperability of Distributed Energy Resources with Associated Electric Power Systems Interfaces" are added. j) Statements have been added to certain figures, tables, schemas, and enumerations throughout the document that indicate that they are reproduced with the permission of the UCA International User Group (UCAIug). These items are derived from the CIM.

  • Standard
    894 pages
    English language
    sale 10% off
    e-Library read for
    1 day
CLC
EN 60870-5-104:2006/A1:2016/AC:2023-09(Corrigendum)
Telecontrol equipment and systems - Part 5-104: Transmission protocols - Network access for IEC 60870-5-101 using standard transport profiles
SIST EN 60870-5-104:2007/A1:2017/AC:2024
  • Corrigendum
    3 pages
    English and French language
    sale 10% off
    e-Library read for
    1 day
CLC
EN IEC 62351-3:2023(Main)
Power systems management and associated information exchange - Data and communications security - Part 3: Communication network and system security - Profiles including TCP/IP
SIST EN IEC 62351-3:2023

IEC 62351-3:2023 specifies how to provide confidentiality, integrity protection, and message level authentication for protocols that make use of TCP/IP as a message transport layer and utilize Transport Layer Security when cyber-security is required. This may relate to SCADA and telecontrol protocols, but also to additional protocols if they meet the requirements in this document. IEC 62351-3 specifies how to secure TCP/IP-based protocols through constraints on the specification of the messages, procedures, and algorithms of Transport Layer Security (TLS) (TLSv1.2 defined in RFC 5246, TLSv1.3 defined in RFC 8446). In the specific clauses, there will be subclauses to note the differences and commonalities in the application depending on the target TLS version. The use and specification of intervening external security devices (e.g., "bump-in-the-wire") are considered out-of-scope. In contrast to previous editions of this document, this edition is self-contained in terms of completely defining a profile of TLS. Hence, it can be applied directly, without the need to specify further TLS parameters, except the port number, over which the communication will be performed. Therefore, this part can be directly utilized from a referencing standard and can be combined with further security measures on other layers. Providing the profiling of TLS without the need for further specifying TLS parameters allows declaring conformity to the described functionality without the need to involve further IEC 62351 documents. This document is intended to be referenced as a normative part of other IEC standards that have the need for providing security for their TCP/IP-based protocol exchanges under similar boundary conditions. However, it is up to the individual protocol security initiatives to decide if this document is to be referenced. The document also defines security events for specific conditions, which support error handling, security audit trails, intrusion detection, and conformance testing. Any action of an organization in response to events to an error condition described in this document are beyond the scope of this document and are expected to be defined by the organization’s security policy. This document reflects the security requirements of the IEC power systems management protocols. Should other standards bring forward new requirements, this document may need to be revised. This second edition cancels and replaces the first edition published in 2014, Amendment 1:2018 and Amendment 2:2020. This edition constitutes a technical revision. This edition includes the following significant technical changes with respect to the previous edition: a) Inclusion of the TLSv1.2 related parameter required in IEC 62351-3 Ed.1.2 to be specified by the referencing standard. This comprises the following parameter: • Mandatory TLSv1.2 cipher suites to be supported. • Specification of session resumption parameters. • Specification of session renegotiation parameters. • Revocation handling using CRL and OCSP. • Handling of security events. b) Inclusion of a TLSv1.3 profile to be applicable for the power system domain in a similar way as for TLSv1.2 session.

  • Standard
    52 pages
    English language
    sale 10% off
    e-Library read for
    1 day
  • Standard
    52 pages
    English language
    sale 10% off
    e-Library read for
    1 day
CLC
EN IEC 62351-9:2023(Main)
Power systems management and associated information exchange - Data and communications security - Part 9: Cyber security key management for power system equipment
SIST EN IEC 62351-9:2023

IEC 62351-9:2023 specifies cryptographic key management, primarily focused on the management of long-term keys, which are most often asymmetric key pairs, such as public-key certificates and corresponding private keys. As certificates build the base this document builds a foundation for many IEC 62351 services (see also Annex A). Symmetric key management is also considered but only with respect to session keys for group-based communication as applied in IEC 62351-6. The objective of this document is to define requirements and technologies to achieve interoperability of key management by specifying or limiting key management options to be used. This document assumes that an organization (or group of organizations) has defined a security policy to select the type of keys and cryptographic algorithms that will be utilized, which may have to align with other standards or regulatory requirements. This document therefore specifies only the management techniques for these selected key and cryptography infrastructures. This document assumes that the reader has a basic understanding of cryptography and key management principles. The requirements for the management of pairwise symmetric (session) keys in the context of communication protocols is specified in the parts of IEC 62351 utilizing or specifying pairwise communication such as: • IEC 62351-3 for TLS by profiling the TLS options • IEC 62351-4 for the application layer end-to-end security • IEC TS 62351-5 for the application layer security mechanism for IEC 60870-5-101/104 and IEEE 1815 (DNP3) The requirements for the management of symmetric group keys in the context of power system communication protocols is specified in IEC 62351-6 for utilizing group security to protect GOOSE and SV communication. IEC 62351-9 utilizes GDOI as already IETF specified group-based key management protocol to manage the group security parameter and enhances this protocol to carry the security parameter for GOOSE, SV, and PTP. This document also defines security events for specific conditions which could identify issues which might require error handling. However, the actions of the organisation in response to these error conditions are beyond the scope of this document and are expected to be defined by the organizations security policy. In the future, as public-key cryptography becomes endangered by the evolution of quantum computers, this document will also consider post-quantum cryptography to a certain extent. Note that at this time being no specific measures are provided. This second edition cancels and replaces the first edition published in 2017. This edition constitutes a technical revision. This edition includes the following significant technical changes with respect to the previous edition: a) Certificate components and verification of the certificate components have been added; b) GDOI has been updated to include findings from interop tests; c) GDOI operation considerations have been added; d) GDOI support for PTP (IEEE 1588) support has been added as specified by IEC/IEEE 61850-9-3 Power Profile; e) Cyber security event logging has been added as well as the mapping to IEC 62351-14; f) Annex B with background on utilized cryptographic algorithms and mechanisms has been added.

  • Standard
    147 pages
    English language
    sale 10% off
    e-Library read for
    1 day