Components
4
Twig Components
8
Render Count
10
ms
Render Time
192.0
MiB
Memory Usage
Components
| Name | Metadata | Render Count | Render Time |
|---|---|---|---|
| ProductState |
"App\Twig\Components\ProductState"components/ProductState.html.twig |
3 | 0.91ms |
| ProductMostRecent |
"App\Twig\Components\ProductMostRecent"components/ProductMostRecent.html.twig |
3 | 2.36ms |
| ProductType |
"App\Twig\Components\ProductType"components/ProductType.html.twig |
1 | 0.30ms |
| ProductCard |
"App\Twig\Components\ProductCard"components/ProductCard.html.twig |
1 | 7.07ms |
Render calls
| ProductState | App\Twig\Components\ProductState | 192.0 MiB | 0.52 ms | |
|---|---|---|---|---|
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DER management systems (DERMS) and microgrid controllers are examples of such systems applied in this guide. In the process of applying the SGIRM-2011, elements were added to reflect the changes that have occurred since 2011 in electric grids. These include the increasing deployment of DER both at the distribution system and, when aggregated, at the transmission system, the increasing role of electricity markets, and business and environmental considerations in their deployment. These elements were added to the SGIRM. The SGIRM defines three integrated architectural perspectives (IAP): power systems, communications and information technology, and business and regulatory requirements. The SGIRM facilitates the implementation of interoperability requirements by establishing relationships between elements of the complete installation, regrouped within IAPs, and by identifying the relevant and applicable standards and rules. The SGIRM can be used to complement design approaches for individual elements of a system and facilitates extensibility, scalability, and upgradeability.<br />\n \t\t\t\t<br />\n This document is a guide to users of IEEE Std 2030™-2011, IEEE Guide for Smart Grid Interoperability of Energy Technology and Information Technology Operation with the Electric Power System (EPS), End-Use Applications, and Loads.6 It provides guidance in applying the smart grid interoperability reference model (SGIRM) of IEEE Std 2030-2011 in the development of control and automation components. This guide outlines approaches to defining the requirements for control and automation applications within the electric power infrastructure, and describing their design, while adhering to a common open architecture.<br />\n Because components of the smart grid are acquired and developed by many different parties, the control and automation systems should be developed according to an open architecture that enables the introduction of common functions across multiple systems and platforms in a way that achieves high levels of modularity, extensibility, portability, and scalability. This guide provides industry-wide common approaches to the design, implementation and life cycle management of smart grid control and automation systems, in a manner that promotes conformance to the smart grid interoperability reference model (SGIRM), hence reducing the number of infrastructures that might otherwise result from competing architectures. Additionally, this recommended practice facilitates the following:--Modular design and design description,--Reusable application software,--Interoperable control and automation applications,--Secure information exchange,--Life cycle affordability, and--Competition and collaboration. This guide supports its users by giving them guidance in the selection or development of computational capabilities, information systems, networks, protocols, frameworks, middleware, resource management, software and operating systems, using both established and evolving industry standards. Standard practices are leveraged to enhance interoperability, operational effectiveness, and the ability to insert future technologies """ #metaKeywords: null #metaDescription: null #shortDescription: "IEEE Guide for Control and Automation Installations Applied to the Electric Power Infrastructure" -notes: "Active" } ] #currentLocale: "en_US" #currentTranslation: null #fallbackLocale: "en_US" #variantSelectionMethod: "match" #productTaxons: Doctrine\ORM\PersistentCollection {#7534 …} #channels: Doctrine\ORM\PersistentCollection {#7628 …} #mainTaxon: Proxies\__CG__\App\Entity\Taxonomy\Taxon {#7309 …} #reviews: Doctrine\ORM\PersistentCollection {#7613 …} #averageRating: 0.0 #images: Doctrine\ORM\PersistentCollection {#7645 …} -supplier: Proxies\__CG__\App\Entity\Supplier\Supplier {#7324 …} -subscriptionCollections: Doctrine\ORM\PersistentCollection {#7321 …} -apiLastModifiedAt: DateTime @1754517600 {#7317 : 2025-08-07 00:00:00.0 Europe/Paris (+02:00) } -lastUpdatedAt: DateTime @1705878000 {#7292 : 2024-01-22 00:00:00.0 Europe/Paris (+01:00) } -author: "" -publishedAt: DateTime @1700607600 {#7318 : 2023-11-22 00:00:00.0 Europe/Paris (+01:00) } -releasedAt: null -confirmedAt: null -canceledAt: DateTime @1700607600 {#7316 : 2023-11-22 00:00:00.0 Europe/Paris (+01:00) } -edition: null -coreDocument: "2030.4" -bookCollection: "" -pageCount: 39 -documents: Doctrine\ORM\PersistentCollection {#7465 …} -favorites: Doctrine\ORM\PersistentCollection {#7500 …} } "showFullLabel" => "true" ] |
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| Component | App\Twig\Components\ProductState {#93055 +product: App\Entity\Product\Product {#7311 #id: 12090 #code: "IEEE00007060" #attributes: Doctrine\ORM\PersistentCollection {#7701 …} #variants: Doctrine\ORM\PersistentCollection {#7744 …} #options: Doctrine\ORM\PersistentCollection {#7916 …} #associations: Doctrine\ORM\PersistentCollection {#7900 …} #createdAt: DateTime @1751040192 {#7274 : 2025-06-27 18:03:12.0 Europe/Paris (+02:00) } #updatedAt: DateTime @1754608621 {#7322 : 2025-08-08 01:17:01.0 Europe/Paris (+02:00) } #enabled: true #translations: Doctrine\ORM\PersistentCollection {#7922 …} #translationsCache: [ "en_US" => App\Entity\Product\ProductTranslation {#7921 #locale: "en_US" #translatable: App\Entity\Product\Product {#7311} #id: 43369 #name: "IEEE 2030.4:2023" #slug: "ieee-2030-4-2023-ieee00007060-243742" #description: """ New IEEE Standard - Active.<br />\n The smart grid interoperability reference model (SGIRM) was developed in IEEE Std 2030™-2011 for systems that integrate, among other assets, distributed energy resources (DER). DER management systems (DERMS) and microgrid controllers are examples of such systems applied in this guide. In the process of applying the SGIRM-2011, elements were added to reflect the changes that have occurred since 2011 in electric grids. These include the increasing deployment of DER both at the distribution system and, when aggregated, at the transmission system, the increasing role of electricity markets, and business and environmental considerations in their deployment. These elements were added to the SGIRM. The SGIRM defines three integrated architectural perspectives (IAP): power systems, communications and information technology, and business and regulatory requirements. The SGIRM facilitates the implementation of interoperability requirements by establishing relationships between elements of the complete installation, regrouped within IAPs, and by identifying the relevant and applicable standards and rules. The SGIRM can be used to complement design approaches for individual elements of a system and facilitates extensibility, scalability, and upgradeability.<br />\n \t\t\t\t<br />\n This document is a guide to users of IEEE Std 2030™-2011, IEEE Guide for Smart Grid Interoperability of Energy Technology and Information Technology Operation with the Electric Power System (EPS), End-Use Applications, and Loads.6 It provides guidance in applying the smart grid interoperability reference model (SGIRM) of IEEE Std 2030-2011 in the development of control and automation components. This guide outlines approaches to defining the requirements for control and automation applications within the electric power infrastructure, and describing their design, while adhering to a common open architecture.<br />\n Because components of the smart grid are acquired and developed by many different parties, the control and automation systems should be developed according to an open architecture that enables the introduction of common functions across multiple systems and platforms in a way that achieves high levels of modularity, extensibility, portability, and scalability. This guide provides industry-wide common approaches to the design, implementation and life cycle management of smart grid control and automation systems, in a manner that promotes conformance to the smart grid interoperability reference model (SGIRM), hence reducing the number of infrastructures that might otherwise result from competing architectures. Additionally, this recommended practice facilitates the following:--Modular design and design description,--Reusable application software,--Interoperable control and automation applications,--Secure information exchange,--Life cycle affordability, and--Competition and collaboration. This guide supports its users by giving them guidance in the selection or development of computational capabilities, information systems, networks, protocols, frameworks, middleware, resource management, software and operating systems, using both established and evolving industry standards. 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| ProductType | App\Twig\Components\ProductType | 192.0 MiB | 0.30 ms | |
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DER management systems (DERMS) and microgrid controllers are examples of such systems applied in this guide. In the process of applying the SGIRM-2011, elements were added to reflect the changes that have occurred since 2011 in electric grids. These include the increasing deployment of DER both at the distribution system and, when aggregated, at the transmission system, the increasing role of electricity markets, and business and environmental considerations in their deployment. These elements were added to the SGIRM. The SGIRM defines three integrated architectural perspectives (IAP): power systems, communications and information technology, and business and regulatory requirements. The SGIRM facilitates the implementation of interoperability requirements by establishing relationships between elements of the complete installation, regrouped within IAPs, and by identifying the relevant and applicable standards and rules. The SGIRM can be used to complement design approaches for individual elements of a system and facilitates extensibility, scalability, and upgradeability.<br />\n \t\t\t\t<br />\n This document is a guide to users of IEEE Std 2030™-2011, IEEE Guide for Smart Grid Interoperability of Energy Technology and Information Technology Operation with the Electric Power System (EPS), End-Use Applications, and Loads.6 It provides guidance in applying the smart grid interoperability reference model (SGIRM) of IEEE Std 2030-2011 in the development of control and automation components. This guide outlines approaches to defining the requirements for control and automation applications within the electric power infrastructure, and describing their design, while adhering to a common open architecture.<br />\n Because components of the smart grid are acquired and developed by many different parties, the control and automation systems should be developed according to an open architecture that enables the introduction of common functions across multiple systems and platforms in a way that achieves high levels of modularity, extensibility, portability, and scalability. This guide provides industry-wide common approaches to the design, implementation and life cycle management of smart grid control and automation systems, in a manner that promotes conformance to the smart grid interoperability reference model (SGIRM), hence reducing the number of infrastructures that might otherwise result from competing architectures. Additionally, this recommended practice facilitates the following:--Modular design and design description,--Reusable application software,--Interoperable control and automation applications,--Secure information exchange,--Life cycle affordability, and--Competition and collaboration. This guide supports its users by giving them guidance in the selection or development of computational capabilities, information systems, networks, protocols, frameworks, middleware, resource management, software and operating systems, using both established and evolving industry standards. Standard practices are leveraged to enhance interoperability, operational effectiveness, and the ability to insert future technologies """ #metaKeywords: null #metaDescription: null #shortDescription: "IEEE Guide for Control and Automation Installations Applied to the Electric Power Infrastructure" -notes: "Active" } ] #currentLocale: "en_US" #currentTranslation: null #fallbackLocale: "en_US" #variantSelectionMethod: "match" #productTaxons: Doctrine\ORM\PersistentCollection {#7534 …} #channels: Doctrine\ORM\PersistentCollection {#7628 …} #mainTaxon: Proxies\__CG__\App\Entity\Taxonomy\Taxon {#7309 …} #reviews: Doctrine\ORM\PersistentCollection {#7613 …} #averageRating: 0.0 #images: Doctrine\ORM\PersistentCollection {#7645 …} -supplier: Proxies\__CG__\App\Entity\Supplier\Supplier {#7324 …} -subscriptionCollections: Doctrine\ORM\PersistentCollection {#7321 …} -apiLastModifiedAt: DateTime @1754517600 {#7317 : 2025-08-07 00:00:00.0 Europe/Paris (+02:00) } -lastUpdatedAt: DateTime @1705878000 {#7292 : 2024-01-22 00:00:00.0 Europe/Paris (+01:00) } -author: "" -publishedAt: DateTime @1700607600 {#7318 : 2023-11-22 00:00:00.0 Europe/Paris (+01:00) } -releasedAt: null -confirmedAt: null -canceledAt: DateTime @1700607600 {#7316 : 2023-11-22 00:00:00.0 Europe/Paris (+01:00) } -edition: null -coreDocument: "2030.4" -bookCollection: "" -pageCount: 39 -documents: Doctrine\ORM\PersistentCollection {#7465 …} -favorites: Doctrine\ORM\PersistentCollection {#7500 …} } ] |
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DER management systems (DERMS) and microgrid controllers are examples of such systems applied in this guide. In the process of applying the SGIRM-2011, elements were added to reflect the changes that have occurred since 2011 in electric grids. These include the increasing deployment of DER both at the distribution system and, when aggregated, at the transmission system, the increasing role of electricity markets, and business and environmental considerations in their deployment. These elements were added to the SGIRM. The SGIRM defines three integrated architectural perspectives (IAP): power systems, communications and information technology, and business and regulatory requirements. The SGIRM facilitates the implementation of interoperability requirements by establishing relationships between elements of the complete installation, regrouped within IAPs, and by identifying the relevant and applicable standards and rules. The SGIRM can be used to complement design approaches for individual elements of a system and facilitates extensibility, scalability, and upgradeability.<br />\n \t\t\t\t<br />\n This document is a guide to users of IEEE Std 2030™-2011, IEEE Guide for Smart Grid Interoperability of Energy Technology and Information Technology Operation with the Electric Power System (EPS), End-Use Applications, and Loads.6 It provides guidance in applying the smart grid interoperability reference model (SGIRM) of IEEE Std 2030-2011 in the development of control and automation components. This guide outlines approaches to defining the requirements for control and automation applications within the electric power infrastructure, and describing their design, while adhering to a common open architecture.<br />\n Because components of the smart grid are acquired and developed by many different parties, the control and automation systems should be developed according to an open architecture that enables the introduction of common functions across multiple systems and platforms in a way that achieves high levels of modularity, extensibility, portability, and scalability. This guide provides industry-wide common approaches to the design, implementation and life cycle management of smart grid control and automation systems, in a manner that promotes conformance to the smart grid interoperability reference model (SGIRM), hence reducing the number of infrastructures that might otherwise result from competing architectures. Additionally, this recommended practice facilitates the following:--Modular design and design description,--Reusable application software,--Interoperable control and automation applications,--Secure information exchange,--Life cycle affordability, and--Competition and collaboration. This guide supports its users by giving them guidance in the selection or development of computational capabilities, information systems, networks, protocols, frameworks, middleware, resource management, software and operating systems, using both established and evolving industry standards. 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| ProductMostRecent | App\Twig\Components\ProductMostRecent | 192.0 MiB | 0.97 ms | |
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| Input props | [ "product" => App\Entity\Product\Product {#7311 #id: 12090 #code: "IEEE00007060" #attributes: Doctrine\ORM\PersistentCollection {#7701 …} #variants: Doctrine\ORM\PersistentCollection {#7744 …} #options: Doctrine\ORM\PersistentCollection {#7916 …} #associations: Doctrine\ORM\PersistentCollection {#7900 …} #createdAt: DateTime @1751040192 {#7274 : 2025-06-27 18:03:12.0 Europe/Paris (+02:00) } #updatedAt: DateTime @1754608621 {#7322 : 2025-08-08 01:17:01.0 Europe/Paris (+02:00) } #enabled: true #translations: Doctrine\ORM\PersistentCollection {#7922 …} #translationsCache: [ "en_US" => App\Entity\Product\ProductTranslation {#7921 #locale: "en_US" #translatable: App\Entity\Product\Product {#7311} #id: 43369 #name: "IEEE 2030.4:2023" #slug: "ieee-2030-4-2023-ieee00007060-243742" #description: """ New IEEE Standard - Active.<br />\n The smart grid interoperability reference model (SGIRM) was developed in IEEE Std 2030™-2011 for systems that integrate, among other assets, distributed energy resources (DER). DER management systems (DERMS) and microgrid controllers are examples of such systems applied in this guide. In the process of applying the SGIRM-2011, elements were added to reflect the changes that have occurred since 2011 in electric grids. These include the increasing deployment of DER both at the distribution system and, when aggregated, at the transmission system, the increasing role of electricity markets, and business and environmental considerations in their deployment. These elements were added to the SGIRM. The SGIRM defines three integrated architectural perspectives (IAP): power systems, communications and information technology, and business and regulatory requirements. The SGIRM facilitates the implementation of interoperability requirements by establishing relationships between elements of the complete installation, regrouped within IAPs, and by identifying the relevant and applicable standards and rules. The SGIRM can be used to complement design approaches for individual elements of a system and facilitates extensibility, scalability, and upgradeability.<br />\n \t\t\t\t<br />\n This document is a guide to users of IEEE Std 2030™-2011, IEEE Guide for Smart Grid Interoperability of Energy Technology and Information Technology Operation with the Electric Power System (EPS), End-Use Applications, and Loads.6 It provides guidance in applying the smart grid interoperability reference model (SGIRM) of IEEE Std 2030-2011 in the development of control and automation components. This guide outlines approaches to defining the requirements for control and automation applications within the electric power infrastructure, and describing their design, while adhering to a common open architecture.<br />\n Because components of the smart grid are acquired and developed by many different parties, the control and automation systems should be developed according to an open architecture that enables the introduction of common functions across multiple systems and platforms in a way that achieves high levels of modularity, extensibility, portability, and scalability. This guide provides industry-wide common approaches to the design, implementation and life cycle management of smart grid control and automation systems, in a manner that promotes conformance to the smart grid interoperability reference model (SGIRM), hence reducing the number of infrastructures that might otherwise result from competing architectures. Additionally, this recommended practice facilitates the following:--Modular design and design description,--Reusable application software,--Interoperable control and automation applications,--Secure information exchange,--Life cycle affordability, and--Competition and collaboration. This guide supports its users by giving them guidance in the selection or development of computational capabilities, information systems, networks, protocols, frameworks, middleware, resource management, software and operating systems, using both established and evolving industry standards. 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The SGIRM can be used to complement design approaches for individual elements of a system and facilitates extensibility, scalability, and upgradeability.<br />\n \t\t\t\t<br />\n This document is a guide to users of IEEE Std 2030™-2011, IEEE Guide for Smart Grid Interoperability of Energy Technology and Information Technology Operation with the Electric Power System (EPS), End-Use Applications, and Loads.6 It provides guidance in applying the smart grid interoperability reference model (SGIRM) of IEEE Std 2030-2011 in the development of control and automation components. This guide outlines approaches to defining the requirements for control and automation applications within the electric power infrastructure, and describing their design, while adhering to a common open architecture.<br />\n Because components of the smart grid are acquired and developed by many different parties, the control and automation systems should be developed according to an open architecture that enables the introduction of common functions across multiple systems and platforms in a way that achieves high levels of modularity, extensibility, portability, and scalability. This guide provides industry-wide common approaches to the design, implementation and life cycle management of smart grid control and automation systems, in a manner that promotes conformance to the smart grid interoperability reference model (SGIRM), hence reducing the number of infrastructures that might otherwise result from competing architectures. Additionally, this recommended practice facilitates the following:--Modular design and design description,--Reusable application software,--Interoperable control and automation applications,--Secure information exchange,--Life cycle affordability, and--Competition and collaboration. This guide supports its users by giving them guidance in the selection or development of computational capabilities, information systems, networks, protocols, frameworks, middleware, resource management, software and operating systems, using both established and evolving industry standards. 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DER management systems (DERMS) and microgrid controllers are examples of such systems applied in this guide. In the process of applying the SGIRM-2011, elements were added to reflect the changes that have occurred since 2011 in electric grids. These include the increasing deployment of DER both at the distribution system and, when aggregated, at the transmission system, the increasing role of electricity markets, and business and environmental considerations in their deployment. These elements were added to the SGIRM. The SGIRM defines three integrated architectural perspectives (IAP): power systems, communications and information technology, and business and regulatory requirements. The SGIRM facilitates the implementation of interoperability requirements by establishing relationships between elements of the complete installation, regrouped within IAPs, and by identifying the relevant and applicable standards and rules. The SGIRM can be used to complement design approaches for individual elements of a system and facilitates extensibility, scalability, and upgradeability.<br />\n \t\t\t\t<br />\n This document is a guide to users of IEEE Std 2030™-2011, IEEE Guide for Smart Grid Interoperability of Energy Technology and Information Technology Operation with the Electric Power System (EPS), End-Use Applications, and Loads.6 It provides guidance in applying the smart grid interoperability reference model (SGIRM) of IEEE Std 2030-2011 in the development of control and automation components. This guide outlines approaches to defining the requirements for control and automation applications within the electric power infrastructure, and describing their design, while adhering to a common open architecture.<br />\n Because components of the smart grid are acquired and developed by many different parties, the control and automation systems should be developed according to an open architecture that enables the introduction of common functions across multiple systems and platforms in a way that achieves high levels of modularity, extensibility, portability, and scalability. This guide provides industry-wide common approaches to the design, implementation and life cycle management of smart grid control and automation systems, in a manner that promotes conformance to the smart grid interoperability reference model (SGIRM), hence reducing the number of infrastructures that might otherwise result from competing architectures. Additionally, this recommended practice facilitates the following:--Modular design and design description,--Reusable application software,--Interoperable control and automation applications,--Secure information exchange,--Life cycle affordability, and--Competition and collaboration. This guide supports its users by giving them guidance in the selection or development of computational capabilities, information systems, networks, protocols, frameworks, middleware, resource management, software and operating systems, using both established and evolving industry standards. 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DER management systems (DERMS) and microgrid controllers are examples of such systems applied in this guide. In the process of applying the SGIRM-2011, elements were added to reflect the changes that have occurred since 2011 in electric grids. These include the increasing deployment of DER both at the distribution system and, when aggregated, at the transmission system, the increasing role of electricity markets, and business and environmental considerations in their deployment. These elements were added to the SGIRM. The SGIRM defines three integrated architectural perspectives (IAP): power systems, communications and information technology, and business and regulatory requirements. The SGIRM facilitates the implementation of interoperability requirements by establishing relationships between elements of the complete installation, regrouped within IAPs, and by identifying the relevant and applicable standards and rules. The SGIRM can be used to complement design approaches for individual elements of a system and facilitates extensibility, scalability, and upgradeability.<br />\n \t\t\t\t<br />\n This document is a guide to users of IEEE Std 2030™-2011, IEEE Guide for Smart Grid Interoperability of Energy Technology and Information Technology Operation with the Electric Power System (EPS), End-Use Applications, and Loads.6 It provides guidance in applying the smart grid interoperability reference model (SGIRM) of IEEE Std 2030-2011 in the development of control and automation components. This guide outlines approaches to defining the requirements for control and automation applications within the electric power infrastructure, and describing their design, while adhering to a common open architecture.<br />\n Because components of the smart grid are acquired and developed by many different parties, the control and automation systems should be developed according to an open architecture that enables the introduction of common functions across multiple systems and platforms in a way that achieves high levels of modularity, extensibility, portability, and scalability. This guide provides industry-wide common approaches to the design, implementation and life cycle management of smart grid control and automation systems, in a manner that promotes conformance to the smart grid interoperability reference model (SGIRM), hence reducing the number of infrastructures that might otherwise result from competing architectures. Additionally, this recommended practice facilitates the following:--Modular design and design description,--Reusable application software,--Interoperable control and automation applications,--Secure information exchange,--Life cycle affordability, and--Competition and collaboration. This guide supports its users by giving them guidance in the selection or development of computational capabilities, information systems, networks, protocols, frameworks, middleware, resource management, software and operating systems, using both established and evolving industry standards. 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| Input props | [ "product" => App\Entity\Product\Product {#7311 #id: 12090 #code: "IEEE00007060" #attributes: Doctrine\ORM\PersistentCollection {#7701 …} #variants: Doctrine\ORM\PersistentCollection {#7744 …} #options: Doctrine\ORM\PersistentCollection {#7916 …} #associations: Doctrine\ORM\PersistentCollection {#7900 …} #createdAt: DateTime @1751040192 {#7274 : 2025-06-27 18:03:12.0 Europe/Paris (+02:00) } #updatedAt: DateTime @1754608621 {#7322 : 2025-08-08 01:17:01.0 Europe/Paris (+02:00) } #enabled: true #translations: Doctrine\ORM\PersistentCollection {#7922 …} #translationsCache: [ "en_US" => App\Entity\Product\ProductTranslation {#7921 #locale: "en_US" #translatable: App\Entity\Product\Product {#7311} #id: 43369 #name: "IEEE 2030.4:2023" #slug: "ieee-2030-4-2023-ieee00007060-243742" #description: """ New IEEE Standard - Active.<br />\n The smart grid interoperability reference model (SGIRM) was developed in IEEE Std 2030™-2011 for systems that integrate, among other assets, distributed energy resources (DER). DER management systems (DERMS) and microgrid controllers are examples of such systems applied in this guide. In the process of applying the SGIRM-2011, elements were added to reflect the changes that have occurred since 2011 in electric grids. These include the increasing deployment of DER both at the distribution system and, when aggregated, at the transmission system, the increasing role of electricity markets, and business and environmental considerations in their deployment. These elements were added to the SGIRM. The SGIRM defines three integrated architectural perspectives (IAP): power systems, communications and information technology, and business and regulatory requirements. The SGIRM facilitates the implementation of interoperability requirements by establishing relationships between elements of the complete installation, regrouped within IAPs, and by identifying the relevant and applicable standards and rules. The SGIRM can be used to complement design approaches for individual elements of a system and facilitates extensibility, scalability, and upgradeability.<br />\n \t\t\t\t<br />\n This document is a guide to users of IEEE Std 2030™-2011, IEEE Guide for Smart Grid Interoperability of Energy Technology and Information Technology Operation with the Electric Power System (EPS), End-Use Applications, and Loads.6 It provides guidance in applying the smart grid interoperability reference model (SGIRM) of IEEE Std 2030-2011 in the development of control and automation components. This guide outlines approaches to defining the requirements for control and automation applications within the electric power infrastructure, and describing their design, while adhering to a common open architecture.<br />\n Because components of the smart grid are acquired and developed by many different parties, the control and automation systems should be developed according to an open architecture that enables the introduction of common functions across multiple systems and platforms in a way that achieves high levels of modularity, extensibility, portability, and scalability. This guide provides industry-wide common approaches to the design, implementation and life cycle management of smart grid control and automation systems, in a manner that promotes conformance to the smart grid interoperability reference model (SGIRM), hence reducing the number of infrastructures that might otherwise result from competing architectures. Additionally, this recommended practice facilitates the following:--Modular design and design description,--Reusable application software,--Interoperable control and automation applications,--Secure information exchange,--Life cycle affordability, and--Competition and collaboration. This guide supports its users by giving them guidance in the selection or development of computational capabilities, information systems, networks, protocols, frameworks, middleware, resource management, software and operating systems, using both established and evolving industry standards. 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DER management systems (DERMS) and microgrid controllers are examples of such systems applied in this guide. In the process of applying the SGIRM-2011, elements were added to reflect the changes that have occurred since 2011 in electric grids. These include the increasing deployment of DER both at the distribution system and, when aggregated, at the transmission system, the increasing role of electricity markets, and business and environmental considerations in their deployment. These elements were added to the SGIRM. The SGIRM defines three integrated architectural perspectives (IAP): power systems, communications and information technology, and business and regulatory requirements. The SGIRM facilitates the implementation of interoperability requirements by establishing relationships between elements of the complete installation, regrouped within IAPs, and by identifying the relevant and applicable standards and rules. The SGIRM can be used to complement design approaches for individual elements of a system and facilitates extensibility, scalability, and upgradeability.<br />\n \t\t\t\t<br />\n This document is a guide to users of IEEE Std 2030™-2011, IEEE Guide for Smart Grid Interoperability of Energy Technology and Information Technology Operation with the Electric Power System (EPS), End-Use Applications, and Loads.6 It provides guidance in applying the smart grid interoperability reference model (SGIRM) of IEEE Std 2030-2011 in the development of control and automation components. This guide outlines approaches to defining the requirements for control and automation applications within the electric power infrastructure, and describing their design, while adhering to a common open architecture.<br />\n Because components of the smart grid are acquired and developed by many different parties, the control and automation systems should be developed according to an open architecture that enables the introduction of common functions across multiple systems and platforms in a way that achieves high levels of modularity, extensibility, portability, and scalability. This guide provides industry-wide common approaches to the design, implementation and life cycle management of smart grid control and automation systems, in a manner that promotes conformance to the smart grid interoperability reference model (SGIRM), hence reducing the number of infrastructures that might otherwise result from competing architectures. Additionally, this recommended practice facilitates the following:--Modular design and design description,--Reusable application software,--Interoperable control and automation applications,--Secure information exchange,--Life cycle affordability, and--Competition and collaboration. This guide supports its users by giving them guidance in the selection or development of computational capabilities, information systems, networks, protocols, frameworks, middleware, resource management, software and operating systems, using both established and evolving industry standards. 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| Input props | [ "product" => App\Entity\Product\Product {#121777 #id: 10550 #code: "IEEE00004593" #attributes: Doctrine\ORM\PersistentCollection {#121760 …} #variants: Doctrine\ORM\PersistentCollection {#121758 …} #options: Doctrine\ORM\PersistentCollection {#121753 …} #associations: Doctrine\ORM\PersistentCollection {#121755 …} #createdAt: DateTime @1751039131 {#121750 : 2025-06-27 17:45:31.0 Europe/Paris (+02:00) } #updatedAt: DateTime @1754607611 {#121785 : 2025-08-08 01:00:11.0 Europe/Paris (+02:00) } #enabled: true #translations: Doctrine\ORM\PersistentCollection {#121771 …} #translationsCache: [ "en_US" => App\Entity\Product\ProductTranslation {#121875 #locale: "en_US" #translatable: App\Entity\Product\Product {#121777} #id: 37209 #name: "IEEE 2030:2011" #slug: "ieee-2030-2011-ieee00004593-242202" #description: """ New IEEE Standard - Inactive-Reserved.<br />\n IEEE Std 2030 provides alternative approaches and best practices for achieving smart grid interoperability. It is the first all-encompassing IEEE standard on smart grid interoperability providing a roadmap directed at establishing the framework in developing an IEEE national and international body of standards based on cross-cutting technical disciplines in power applications and information exchange and control through communications. IEEE Std 2030 establishes the smart grid interoperability reference model (SGIRM) and provides a knowledge base addressing terminology, characteristics, functional performance and evaluation criteria, and the application of engineering principles for smart grid interoperability of the electric power system with end-use applications and loads. A system of systems approach to smart grid interoperability lays the foundation on which IEEE Std 2030 establishes the SGIRM as a design tool that inherently allows for extensibility, scalability, and upgradeability. The IEEE 2030 SGIRM defines three integrated architectural perspectives: power systems, communications technology, and information technology. Additionally, it defines design tables and the classification of data flow characteristics necessary for interoperability. Guidelines for smart grid interoperability, design criteria, and reference model applications are addressed with emphasis on functional interface identification, logical connections and data flows, communications and linkages, digital information management, and power generation usage.<br />\n \t\t\t\t<br />\n This document provides guidelines for smart grid interoperability. It also provides a knowledge base addressing terminology, characteristics, functional performance and evaluation criteria, and the application of engineering principles for smart grid interoperability of the electric power system (EPS) with end-use applications and loads. The guide discusses alternate approaches to good practices for the Smart Grid.<br />\n This document provides guidelines in understanding and defining smart grid interoperability of the EPS with end-use applications and loads. Integration of energy technology and information and communications technology (ICT) is necessary to achieve seamless operation for electric generation, delivery, and end-use benefits to permit two-way power flow with communication and control. Interconnection and intra-facing frameworks and strategies with design definitions are addressed in this guide, providing guidance in expanding the current knowledge base. This expanded knowledge base is needed as a key element in grid architectural designs and operation to promote a more reliable and flexible EPS. 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