BS EN IEC 61280-2-13:2024 Fibre Optic Communication Subsystem Test Procedures

Introducing the BS EN IEC 61280-2-13:2024, a comprehensive standard that provides essential guidelines for testing fibre optic communication subsystems. This standard is crucial for professionals in the field of digital communication systems, offering a detailed methodology for the measurement of error vector magnitude (EVM), a key parameter in assessing the performance of digital communication systems.

Overview

The BS EN IEC 61280-2-13:2024 standard is a pivotal document for engineers and technicians working with fibre optic communication systems. Released on November 26, 2024, this standard is the latest in a series of guidelines that ensure the reliability and efficiency of digital communication systems. With a total of 30 pages, it provides a thorough exploration of test procedures, focusing on the measurement of error vector magnitude, which is critical for maintaining the integrity of data transmission.

Key Features

• Standard Number: BS EN IEC 61280-2-13:2024
• Pages: 30
• Release Date: November 26, 2024
• ISBN: 978 0 539 26996 3
• Status: Standard

Importance of Error Vector Magnitude (EVM)

Error Vector Magnitude (EVM) is a critical parameter in the evaluation of digital communication systems. It quantifies the performance of a communication system by measuring the deviation of the actual transmitted signal from the ideal signal. A lower EVM indicates a higher quality of signal transmission, which is essential for ensuring the accuracy and reliability of data communication.

The BS EN IEC 61280-2-13:2024 standard provides a detailed methodology for measuring EVM, enabling professionals to accurately assess and optimize the performance of fibre optic communication systems. By adhering to these guidelines, engineers can ensure that their systems meet the required standards for signal integrity and data accuracy.

Who Should Use This Standard?

This standard is indispensable for a wide range of professionals, including:

• Telecommunications Engineers: Ensuring the optimal performance of communication networks.
• Quality Assurance Specialists: Verifying that systems meet industry standards for signal quality.
• Research and Development Teams: Developing new technologies and improving existing systems.
• Technical Educators: Teaching the principles of fibre optic communication and system testing.

Benefits of Using BS EN IEC 61280-2-13:2024

By implementing the guidelines set forth in this standard, organizations can achieve several benefits:

• Enhanced Signal Quality: By accurately measuring and minimizing EVM, systems can achieve superior signal quality, leading to more reliable communication.
• Increased System Reliability: Adhering to standardized test procedures ensures that systems are robust and capable of maintaining performance under various conditions.
• Regulatory Compliance: Meeting industry standards is crucial for compliance with regulatory requirements, avoiding potential legal and financial penalties.
• Competitive Advantage: Organizations that implement rigorous testing procedures can offer higher quality services, gaining a competitive edge in the market.

Conclusion

The BS EN IEC 61280-2-13:2024 standard is an essential resource for anyone involved in the design, implementation, and maintenance of fibre optic communication systems. By providing a clear and detailed methodology for measuring error vector magnitude, this standard helps ensure that digital communication systems operate at peak performance, delivering reliable and accurate data transmission.

Whether you are an engineer, a quality assurance specialist, or a researcher, the guidelines provided in this standard will be invaluable in your efforts to optimize the performance of fibre optic communication systems. Embrace the latest advancements in communication technology with the BS EN IEC 61280-2-13:2024 and ensure your systems are at the forefront of industry standards.

BS EN IEC 61280-2-13:2024

This standard BS EN IEC 61280-2-13:2024 Fibre optic communication subsystem test procedures is classified in these ICS categories:

• 33.180.10 Fibres and cables

IEC 61280-2-13:2024 series defines a procedure for calculating the root-mean-square error vector magnitude of optical n-APSK signals from a set of measured symbols. It specifically defines the normalization of the reference states and a procedure for optimal scaling of the measured symbol states. The procedure described in this document applies to single-polarized optical signals as well as to conventional polarization-multiplexed signals with independently modulated polarization tributaries. In general, it is not advisable to apply these procedures without modification to signals, in which optical amplitude, phase, and polarization state are simultaneously modulated to encode the information data. This document does not specify any signal processing steps for extracting the symbols from the received optical signals, because these steps depend on the optical receiver and can vary with the type of the transmitted n-APSK signal. These and optional additional signal processing steps are defined in application-specific documents.