Open Smart Grid Protocol Explained

The Open Smart Grid Protocol (OSGP) is a family of specifications published by the European Telecommunications Standards Institute (ETSI) used in conjunction with the ISO/IEC 14908 control networking standard for smart grid applications. OSGP is optimized to provide reliable and efficient delivery of command and control information for smart meters, direct load control modules, solar panels, gateways, and other smart grid devices. With over 5 million OSGP based smart meters and devices deployed worldwide it is one of the most widely used smart meter and smart grid device networking standards.

Protocol layers and features

OSGP follows a modern, structured approach based on the OSI protocol model to meet the evolving challenges of the smart grid.

At the application layer, ETSI TS 104 001 provides a table-oriented data storage based, in part, on the ANSI C12.19 / MC12.19 / 2012 / IEEE Std 1377 standards for Utility Industry End Device Data Tables and ANSI C12.18 / MC12.18 / IEEE Std 1701, standard Protocol Specification for ANSI Type 2 Optical Port for its services and payload encapsulation. This standard and command system that provides for not only smart meters and related data but for general purpose extension to other smart grid devices.

ETSI TS 104 001 is an updated version of the application layer specification that incorporates enhanced security features, including AES 128 encryption, and replaces the previously ETSI GS OSG 001 version. OSGP is designed to be very bandwidth efficient, enabling it to offer high performance and low cost using bandwidth constrained media such as the power line. For example, just as SQL provides an efficient and flexible database query language for enterprise applications, OSGP provides an efficient and flexible query language for smart grid devices. As with SQL, OSGP supports reading and writing of single attributes, multiple elements, or even entire tables. As another example, OSGP includes capabilities for an adaptive, directed meshing system that enables any OSGP device to serve as a message repeater, further optimizing bandwidth use by repeating only those packets that need to be repeated. OSGP also includes authentication and encryption for all exchanges to protect the integrity and privacy of data as is required in the smart grid.

The intermediate layers of the OSGP stack leverage the ISO/IEC 14908 control networking standard, a field-proven multi-application widely used in smart grid, smart city, and smart building applications with more than 100 million devices deployed worldwide. ISO/IEC 14908 is highly optimized for efficient, reliable, and scalable control networking applications. The low overhead of ISO/IEC 14908 enables it to deliver high performance without requiring high bandwidth.

Since it builds on ISO/IEC 14908, which is media independent, OSGP has the possibility to be used with any current or future physical media. OSGP today uses ETSI TS 103 908 (PowerLine Telecommunications) as its physical layer. Although a new standard, products that conform to ETSI TS 103 908 prior to its formal adoption have been on the market for many years, with over 40 million smart meter and grid devices deployed.[1]

In 2020, IEC approved and published an International Standard (IEC 62056-8-8) defining the OSGP Communication Profile for the DLMS/COSEM suite of standards.

In addition, CEN/CENELEC approved and published a standard (CLC/TS 50586) for OSGP that describes its data interface model, application-level communication, management functionalities, and security mechanism for the exchange of data with smart-grid devices.

Both of these standards were part of the outcomes of the EU Smart Metering Mandate M/441 and its decision identifying OSGP as one of the protocols that can be used for Smart Metering deployments in Europe.

It is also important to define interoperability between information systems and applications, and this needs to be ensured independent of the physical layers. This is achieved using NTA 8150, which defines APIs higher level web services protocols (e.g. SOAP and xml). The NTA 8150 consists of two parts; 1) System Software API, description of the architecture and the API for AMI; 2) API usage per use case, description for specific AMI use cases, as examples.

Standards

OSGP is built upon the following open standards.

OSGP is supported and maintained by the OSGP Alliance (formerly known as Energy Services Network Association), a non-profit corporation composed of utilities, manufacturers and system integrators.

See also

External links

Notes and References

  1. http://www.etsi.org/WebSite/NewsandEvents/2012_01_Open_Smart_Grid.aspx ETSI Approves Open Smart Grid Protocol (OSGP) for Grid Technologies
  2. http://www.etsi.org/deliver/etsi_ts/104000_104099/104001/02.01.01_60/ts_104001v020101p.pdf ETSI Technical specification TS 104 001: Open Smart Grid Protocol
  3. http://www.iso.org/iso/iso_catalogue/catalogue_tc/catalogue_detail.htm?csnumber=60203 ISO/IEC 14908-1
  4. http://www.etsi.org/deliver/etsi_ts/103900_103999/103908/01.01.01_60/ts_103908v010101p.pdf ETSI Technical specification TS 103 908: Powerline Telecommunications (PLT)
  5. Web site: IEC 62056-8-8:2020 | IEC Webstore.
  6. Web site: News events.
  7. https://shop.bsigroup.com/ProductDetail?pid=000000000030382514
  8. https://www.nema.org/Standards/ComplimentaryDocuments/C12-19-2012-Contents-and-Scope.pdf ANSI C12.19, American National Standardfor Utility Industry End Device Data Tables.
  9. https://www.ecmx.org/public/Resources/Documents/standards/mc/MC1219-2013-intro.pdf MC12.19, Utility Industry Metering Communication Protocol Application Layer (End Device Data Tables)
  10. https://www.nema.org/Standards/ComplimentaryDocuments/ANSI-C12-18.pdf ANSI C12.18-2006, American National Standard, Protocol Specification for ANSI Type 2 Optical Port.
  11. https://www.ecmx.org/public/Resources/Documents/standards/mc/MC1218-2013-intro.pdf MC12.18, ANSI Type II Optical Port Communication Protocol Complement for the Utility Industry End Device Data Tables.
  12. Web site: NTA 8150-1:2010 en.
  13. Web site: NTA 8150-2:2010 en.