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Smart Grids IEEE P2030
Claudio LimaVice Chair of IEEE P2030 Smart Grid Communications Architecture SG1
ETSI Workshop - Standards: An Architecture for the Smart Grid
France, April 5th 2011Copyright©2011All rights reserved
Disclaimer
The information contained here does not necessarily
expresses the final opinion of the IEEE P2030 since
this is still an working in progress. But it provides
the basis for ongoing standards development
discussions.discussions.
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IEEE P2030 Smart Grid Key Highlights• The IEEE P2030 is a Standard Guide for Smart Grid
Interoperability.
• It addresses the basic Smart Grid definitions, frameworks,
challenges and three different architectural perspectives
(Power & Energy, Communications and IT) with
interoperability tables and charts.
• The architectures adopts a methodic end-to-end and system
engineering approach to address the secure, modular and engineering approach to address the secure, modular and
scalable Smart Grid interfaces and building blocks.
• IEEE P2030 has been voted and approved for ballot in the
last General Plenary meeting (New Orleans, Feb 2011).
• The IEEE 2030 Series of standards will address more specific
technologies and implementation of Smart Grid system (e.g.
P2030.1 Electric Vehicle, P2030.2 Storage Energy Systems).
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Source: IEEE
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IEEE P2030 Smart Grid Interoperability TimelineIEEE P2030 Smart Grid Interoperability TimelineIEEE P2030 Smart Grid Interoperability TimelineIEEE P2030 Smart Grid Interoperability Timeline
Almost DONE!
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IEEE P2030 Smart Grid
Generic Framework
Methodological Interoperability
Framework composed of:
• Three Interoperability
Architecture Perspectives
(IAP):
• Power System (PS)• Power System (PS)
• Communications
Technology (CT)
• Information
Technology (IT)
• IAPs Interoperability Tables
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Source: IEEE
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Using the System Engineering ApproachUsing the System Engineering ApproachUsing the System Engineering ApproachUsing the System Engineering Approach
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TwoTwoTwoTwo----Levels SG System ArchitectureLevels SG System ArchitectureLevels SG System ArchitectureLevels SG System Architecture
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The Smart Grid Foundational LayersThe Smart Grid Foundational LayersThe Smart Grid Foundational LayersThe Smart Grid Foundational Layers
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Key Attributes1. Broadest, All Inclusive Architecture (provide
alternative paths).
2. Adopt a System Engineering Approach.
3. Define Key Actors and Critical Interfaces.
4. Methodological and Well Documented Procedure.
5. Top Down Approach (System to Sub-System Level).
6. Secure, Modular, Scalable and Interoperable. 6. Secure, Modular, Scalable and Interoperable.
(define demarcation points between “entities/actors”).
7. Use Technology Neutral Approach.
8. Dynamic and Evolving Architecture.
9. Covers the Whole Utility Smart Grid Spectrum.
10. Useful to Stakeholders (utilities, vendors, SDOs, etc).
11. Seeks an International Perspective.
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Source: IEEE
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Important Smart Grid Design PrinciplesImportant Smart Grid Design PrinciplesImportant Smart Grid Design PrinciplesImportant Smart Grid Design Principles• Secure
• Reliable
• Scalable “Open”
Standards-BasedRecommended
Smart Grid
• Manageable
• Modular
• Future Proof
Standards-Based
Interoperable
Smart Grid
Characteristics
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The Smart Grid Building BlocksThe Smart Grid Building BlocksThe Smart Grid Building BlocksThe Smart Grid Building Blocks
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Source: IEEE
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IEEE P2030 Smart Grid Communications IEEE P2030 Smart Grid Communications IEEE P2030 Smart Grid Communications IEEE P2030 Smart Grid Communications
Reference Architecture (SGReference Architecture (SGReference Architecture (SGReference Architecture (SG----CRA)CRA)CRA)CRA)
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Source: IEEE P2030
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SG Architecture Development Methodology
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Source: IEEE P2030
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IEEE P2030 Smart Grid Work: Architectures
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IEEE P2030 Smart Grid Work: Tables & Charts
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IEEE P2030
Architecture Perspectives
Appendix
Architecture Perspectives
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Source: IEEE
IEEE P2030 Communications Technology
Interoperability Architecture Perspective (CT-IAP)
Source: IEEE
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IEEE P2030 Power System
Interoperability Architecture Perspective (PS-IAP)
Source: IEEE
All Rights Reserved to the IEEE
IEEE P2030 Information Technology
Interoperability Architecture Perspective (IT-IAP)
Source: IEEE
All Rights Reserved to the IEEE
IEEE P2030
Interoperability TablesInteroperability Tables
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Source: IEEE
Example of Detailed Communications (CT) Interface Description
Source: IEEE
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IT Interfaces/Data Flows Description Table
Source: IEEE
All Rights Reserved to the IEEE
Power System Interfaces Types and Descriptions
Source: IEEE
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Sample Smart Grid Interface/ Application Mapping Table
Source: IEEE
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Typical Data Characteristics of Sample Applications
Source: IEEE
All Rights Reserved to the IEEE
IEEE P2030 Contact Information
For more information about the IEEE P2030, 2030 Standards Series
(e.g. P2030.1 - Electric Vehicles, P2030.2 - Storage Energy Systems,
P2030.3 - Testing Storage Energy Systems, etc), collaboration and
partnership opportunities please contact:
http://grouper.ieee.org/groups/scc21/2030/2030_index.html
All Rights Reserved to the IEEE
Source: IEEE
Dick DeBlasio – IEEE P2030 ChairEmail: [email protected], Phone: +1 303 275 4333
Thomas Basso – IEEE P2030 SecretaryEmail: [email protected], Phone: +1 303 275 3753
Bill Ash – Strategic Program Manager, IEEE-SAEmail: [email protected], Phone: +1 732 465 5828
Claudio Lima