Active Standard

IEEE 487.2-2013

IEEE Standard for the Electrical Protection of Communication Facilities Serving Electric Supply Locations through the Use of Optical Fiber Systems

Safe and reliable methods for the electrical protection of telecommunication facilities serving electric supply locations through the use of optical fiber systems for the entire facility are presented in this standard.

Sponsor Committee
PE/PSCC - Power System Communications and Cybersecurity
Learn More About PE/PSCC - Power System Communications and Cybersecurity
Status
Active Standard
PAR Approval
2012-11-02
Board Approval
2013-08-23
History
Published:
2013-09-20

Working Group Details

Society
IEEE Power and Energy Society
Learn More About IEEE Power and Energy Society
Sponsor Committee
PE/PSCC - Power System Communications and Cybersecurity
Learn More About PE/PSCC - Power System Communications and Cybersecurity
Working Group
P487.2 WG - P487.2 Working Group
IEEE Program Manager
Tom Thompson
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Working Group Chair
Percy Pool

Other Activities From This Working Group

Current projects that have been authorized by the IEEE SA Standards Board to develop a standard.


No Active Projects

Standards approved by the IEEE SA Standards Board that are within the 10-year lifecycle.


1692-2023

IEEE Approved Draft Guide for the Protection of Communication Installations from Lightning Effects

The document addresses methods and practices necessary to reduce the risk of damages to communications equipment within structures arising from lightning surges causing GPR (ground potential rise) and similar potential differences.

Learn More About 1692-2023

487.3-2014

IEEE Standard for the Electrical Protection of Communication Facilities Serving Electric Supply Locations Through the Use of Hybrid Facilities

Safe and reliable methods for the electrical protection of telecommunication facilities serving electric supply locations through the use of metallic wire-line components in part of the telecommunication circuit and optical fiber systems in the remainder of the telecommunication circuit are presented in this standard. Hybrid applications have an equipment junction between the metallic wire-line and the fiber cable, i.e., a wire-line-fiber cable junction (CFJ).

Learn More About 487.3-2014

487.3a-2022

IEEE Standard for the Electrical Protection of Communication Facilities Serving Electric Supply Locations Through the Use of Hybrid Facilities - Amendment 1

Safe and reliable methods for the electrical protection of telecommunication facilities serving electric supply locations through the use of metallic wire-line components in part of the telecommunication circuit, and optical fiber systems in the remainder of the telecommunication circuit are presented in this standard. Hybrid applications have an equipment junction between the metallic wire-line and the optical fiber cable, i.e., a wire-line-fiber cable junction (CFJ).

Learn More About 487.3a-2022

487.4-2013

IEEE Standard for the Electrical Protection of Communication Facilities Serving Electric Supply Locations Through the Use of Neutralizing Transformers

Engineering design procedures for the electrical protection of communication facilities serving electric supply locations through the use of neutralizing transformers are presented in this standard.

Learn More About 487.4-2013

487.5-2013

IEEE Standard for the Electrical Protection of Communication Facilities Serving Electric Supply Locations Through the Use of Isolation Transformers

Engineering design procedures for the electrical protection of communication facilities serving electric supply locations through the use of isolation transformers are presented in this standard. These isolation transformers are hard-wired (i.e., have no plug-in units and are not modular).

Learn More About 487.5-2013

789-2013

IEEE Standard Performance Requirements for Communications and Control Cables for Application in High-Voltage Environments

Information to assist in determining the electrical parameters of communication and control cables necessary to improve the overall reliability of these cables when used in high-voltage environments is the objective of this standard. There should be a very high probability (greater than 99%) that these cables will perform their intended function for specified periods of time in high-voltage interference conditions. The end result being more reliable communications over said cables. The information presented in this standard will apply equally to either new or existing [already installed] cables.

Learn More About 789-2013

These standards have been replaced with a revised version of the standard, or by a compilation of the original active standard and all its existing amendments, corrigenda, and errata.


No Superseded Standards

These standards have been removed from active status through a ballot where the standard is made inactive as a consensus decision of a balloting group.


No Inactive-Withdrawn Standards

These standards are removed from active status through an administrative process for standards that have not undergone a revision process within 10 years.


1692-2011

IEEE Guide for the Protection of Communication Installations from Lightning Effects

The document addresses methods and practices necessary to reduce the risk of damages to communications equipment within structures arising from lightning surges causing GPR (ground potential rise) and similar potential differences.

Learn More About 1692-2011

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