SIST EN IEC 61280-4-2:2024
(Main)Fibre-optic communication subsystem test procedures - Part 4-2: Installed cabling plant - Single-mode attenuation and optical return loss measurements (IEC 61280-4-2:2024)
Fibre-optic communication subsystem test procedures - Part 4-2: Installed cabling plant - Single-mode attenuation and optical return loss measurements (IEC 61280-4-2:2024)
IEC 61280-4-2:2024 is available as IEC 61280-4-2:2024 RLV which contains the International Standard and its Redline version, showing all changes of the technical content compared to the previous edition.
IEC 62180-4-2:2024 is applicable to the measurements of attenuation and optical return loss of an installed optical fibre cabling plant using single-mode fibre. This cabling plant can include single-mode optical fibres, connectors, adapters, splices, and other passive devices. The cabling can be installed in a variety of environments including residential, commercial, industrial and data centre premises, as well as outside plant environments. This document is applicable to all single-mode fibre types including those designated by IEC 60793-2-50 as Class B fibres. The principles of this document can be applied to cabling plants containing branching devices (splitters) and at specific wavelength ranges in situations where passive wavelength selective components are deployed, such as WDM, CWDM and DWDM devices. This document is not intended to apply to cabling plants that include active devices such as fibre amplifiers or dynamic channel equalizers. This third edition cancels and replaces the second edition published in 2014. This edition constitutes a technical revision. This edition includes the following significant technical changes with respect to the previous edition:
a) addition of the equipment cord method;
b) addition of test limit adjustment related to test cord grades;
c) refinements on measurement uncertainties.
Prüfverfahren für Lichtwellenleiter-Kommunikationsuntersysteme - Teil 4-2: Installierte Kabelanlagen - Einmoden-Dämpfungs- und optische Rückflussdämpfungsmessung (IEC 61280-4-2:2024)
Procédures d’essai des sous-systèmes de télécommunication fibroniques - Partie 4-2: Installations câblées - Mesure de l'affaiblissement de réflexion optique et de l'affaiblissement des fibres unimodales (IEC 61280-4-2:2024)
IEC 61280-4-2:2024 est disponible sous forme de IEC 61280-4-2:2024 RLV qui contient la Norme internationale et sa version Redline, illustrant les modifications du contenu technique depuis l'édition précédente.
L'IEC 61280-4-2:2024 s’applique aux mesures de l’affaiblissement et de l’affaiblissement de réflexion optique d’une installation câblée à fibres optiques utilisant des fibres unimodales. Cette installation câblée peut inclure des fibres optiques unimodales, des connecteurs, des adaptateurs, des épissures et d’autres dispositifs passifs. Le câblage peut être installé dans une diversité d’environnements, notamment dans des locaux résidentiels, commerciaux ou industriels et des centres de traitement de données, ainsi que dans des environnements d’installations extérieures. Le présent document s’applique à tous les types de fibres unimodales, y compris celles désignées comme des fibres de Classe B par l’IEC 60793-2-50. Les principes du présent document peuvent s’appliquer aux installations câblées contenant des dispositifs de commutation (répartiteurs) et sur des plages de longueurs d’onde spécifiques, dans des situations dans lesquelles sont déployés des composants passifs sélectifs en longueurs d’onde, par exemple des dispositifs WDM, CWDM et DWDM. Le présent document n’est pas destiné à s’appliquer à des installations câblées qui incluent des dispositifs actifs tels que des amplificateurs à fibres ou des égaliseurs de canaux de transmission dynamiques. Cette troisième édition annule et remplace la deuxième édition parue en 2014. Cette édition constitue une révision technique. Cette édition inclut les modifications techniques majeures suivantes par rapport à l’édition précédente:
a) ajout de la méthode des cordons d’équipement;
b) ajout de l’ajustement de limite d’essai lié aux classes de cordons d’essai;
c) affinements des incertitudes de mesure.
Postopki za preskušanje optičnih komunikacijskih podsistemov - 4-2. del: Kabelska inštalacija - Meritve slabljenja v enorodovnih vlaknih in optičnih povratnih izgub (IEC 61280-4-2:2024)
Ta del standarda IEC 61280 se uporablja za meritve slabljenja in optičnih povratnih izgub kabelskih inštalacij optičnih vlaken z enorodnimi vlakni. Ta kabelska inštalacija lahko vključuje enorodna optična vlakna, konektorje, vmesnike, spojnice in druge pasivne naprave. Kable je mogoče položiti v različnih okoljih, vključno s stanovanjskimi, poslovnimi, industrijskimi prostori in prostori podatkovnih centrov, ter tudi v okoljih zunanjih inštalacij.
Ta dokument se uporablja za vse vrste enorodnih vlaken, vključno s tistimi, določenimi v standardu IEC 60793-2-50 kot vlakna razreda B.
Načela tega dokumenta je mogoče uporabiti za kabelske inštalacije z razvejilnimi elementi (delilniki) in v določenem razponu valovne dolžine v situacijah, kjer so razmeščene pasivne valovnodolžinske selektivne komponente, kot so naprave WDM, CWDM in DWDM.
Ta dokument ni namenjen za uporabo pri kabelskih inštalacijah z aktivnimi napravami, kot so ojačevalniki optičnih vlaken ali dinamični kanalni stabilizatorji.
General Information
Relations
Overview
SIST EN IEC 61280-4-2:2024 (identical to IEC 61280-4-2:2024) defines test procedures for measuring single-mode attenuation and optical return loss (ORL) in an installed optical fibre cabling plant. The standard covers passive installed components - fibres, connectors, adapters, splices and other passive devices - across environments such as residential, commercial, industrial, data centres and outside plant. It applies to all single‑mode fibre types (including IEC 60793-2-50 Class B) and can be applied where passive wavelength‑selective components (WDM/CWDM/DWDM) are present. It is not intended for cabling plants containing active devices (e.g., fibre amplifiers).
IEC 61280-4-2:2024 is the third edition and introduces notable updates: the equipment cord method, test limit adjustments related to test cord grades, and refinements to measurement uncertainties. The International Standard (and its redline version) is available here: IEC 61280-4-2:2024 RLV.
Key topics and technical requirements
- Measurement methods: multiple methods are normative - one‑cord, two‑cord, three‑cord reference methods, the new equipment cord method, and OTDR‑based procedures.
- Attenuation and ORL definitions: consistent terminology, graphical symbols and calculation rules for single‑mode attenuation and optical return loss.
- Apparatus requirements: specifications for light sources, launch/tail/test cords, power meters (LSPM), OTDRs and return loss test sets; emphasis on stability and spectral characteristics.
- Uncertainty and calibration: guidance on major uncertainty sources (test cords, power meter, source stability, reflections), bi‑directional measurements, and calibration procedures.
- Procedures and documentation: step‑by‑step test procedures, calculations, inspection/cleaning of end faces, and mandatory test reporting content.
- Annexes: normative annexes A–E provide detailed procedures for each method, including OTDR guidance and how to report components of measured attenuation.
Practical applications and users
This standard is intended for professionals who certify, install and maintain single‑mode cabling plants:
- Test technicians and certifiers performing attenuation and ORL verification
- Data centre and network infrastructure engineers validating fibre links
- Telecommunications contractors installing outside plant and building backbone cabling
- Laboratories and manufacturers developing test equipment or producing test cords
- Procurement and standards authors specifying acceptance criteria for single‑mode installations
Use IEC 61280-4-2:2024 to ensure consistent, repeatable single‑mode attenuation and optical return loss measurements, to adjust test limits for cord grades, and to document measurement uncertainty in acceptance reports.
Related standards
- IEC 60793‑2‑50 (single‑mode fibre classes)
- IEC 61300 series (connector inspection and cleaning)
- IEC 61315 (power meter calibration)
- IEC 61746‑1 (OTDR calibration and use)
Keywords: single-mode attenuation, optical return loss, installed cabling plant, IEC 61280-4-2:2024, equipment cord method, OTDR, test cord grades, measurement uncertainty.
Frequently Asked Questions
SIST EN IEC 61280-4-2:2024 is a standard published by the Slovenian Institute for Standardization (SIST). Its full title is "Fibre-optic communication subsystem test procedures - Part 4-2: Installed cabling plant - Single-mode attenuation and optical return loss measurements (IEC 61280-4-2:2024)". This standard covers: <!-- NEW! -->IEC 61280-4-2:2024 is available as <a href="https://webstore.iec.ch/publication/94681">IEC 61280-4-2:2024 RLV</a> which contains the International Standard and its Redline version, showing all changes of the technical content compared to the previous edition.</br></br>IEC 62180-4-2:2024 is applicable to the measurements of attenuation and optical return loss of an installed optical fibre cabling plant using single-mode fibre. This cabling plant can include single-mode optical fibres, connectors, adapters, splices, and other passive devices. The cabling can be installed in a variety of environments including residential, commercial, industrial and data centre premises, as well as outside plant environments. This document is applicable to all single-mode fibre types including those designated by IEC 60793-2-50 as Class B fibres. The principles of this document can be applied to cabling plants containing branching devices (splitters) and at specific wavelength ranges in situations where passive wavelength selective components are deployed, such as WDM, CWDM and DWDM devices. This document is not intended to apply to cabling plants that include active devices such as fibre amplifiers or dynamic channel equalizers. This third edition cancels and replaces the second edition published in 2014. This edition constitutes a technical revision. This edition includes the following significant technical changes with respect to the previous edition: a) addition of the equipment cord method; b) addition of test limit adjustment related to test cord grades; c) refinements on measurement uncertainties.
<!-- NEW! -->IEC 61280-4-2:2024 is available as <a href="https://webstore.iec.ch/publication/94681">IEC 61280-4-2:2024 RLV</a> which contains the International Standard and its Redline version, showing all changes of the technical content compared to the previous edition.</br></br>IEC 62180-4-2:2024 is applicable to the measurements of attenuation and optical return loss of an installed optical fibre cabling plant using single-mode fibre. This cabling plant can include single-mode optical fibres, connectors, adapters, splices, and other passive devices. The cabling can be installed in a variety of environments including residential, commercial, industrial and data centre premises, as well as outside plant environments. This document is applicable to all single-mode fibre types including those designated by IEC 60793-2-50 as Class B fibres. The principles of this document can be applied to cabling plants containing branching devices (splitters) and at specific wavelength ranges in situations where passive wavelength selective components are deployed, such as WDM, CWDM and DWDM devices. This document is not intended to apply to cabling plants that include active devices such as fibre amplifiers or dynamic channel equalizers. This third edition cancels and replaces the second edition published in 2014. This edition constitutes a technical revision. This edition includes the following significant technical changes with respect to the previous edition: a) addition of the equipment cord method; b) addition of test limit adjustment related to test cord grades; c) refinements on measurement uncertainties.
SIST EN IEC 61280-4-2:2024 is classified under the following ICS (International Classification for Standards) categories: 33.180.01 - Fibre optic systems in general. The ICS classification helps identify the subject area and facilitates finding related standards.
SIST EN IEC 61280-4-2:2024 has the following relationships with other standards: It is inter standard links to SIST EN 61280-4-2:2014. Understanding these relationships helps ensure you are using the most current and applicable version of the standard.
You can purchase SIST EN IEC 61280-4-2:2024 directly from iTeh Standards. The document is available in PDF format and is delivered instantly after payment. Add the standard to your cart and complete the secure checkout process. iTeh Standards is an authorized distributor of SIST standards.
Standards Content (Sample)
SLOVENSKI STANDARD
01-september-2024
Postopki za preskušanje optičnih komunikacijskih podsistemov - 4-2. del:
Kabelska inštalacija - Meritve slabljenja v enorodovnih vlaknih in optičnih
povratnih izgub (IEC 61280-4-2:2024)
Fibre-optic communication subsystem test procedures - Part 4-2: Installed cabling plant -
Single-mode attenuation and optical return loss measurements (IEC 61280-4-2:2024)
Prüfverfahren für Lichtwellenleiter-Kommunikationsuntersysteme - Teil 4-2: Installierte
Kabelanlagen - Einmoden-Dämpfungs- und optische Rückflussdämpfungsmessung (IEC
61280-4-2:2024)
Procédures d’essai des sous-systèmes de télécommunication fibroniques - Partie 4-2:
Installations câblées - Mesure de l'affaiblissement de réflexion optique et de
l'affaiblissement des fibres unimodales (IEC 61280-4-2:2024)
Ta slovenski standard je istoveten z: EN IEC 61280-4-2:2024
ICS:
33.180.01 Sistemi z optičnimi vlakni na Fibre optic systems in
splošno general
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.
EUROPEAN STANDARD EN IEC 61280-4-2
NORME EUROPÉENNE
EUROPÄISCHE NORM June 2024
ICS 33.180.01 Supersedes EN 61280-4-2:2014
English Version
Fibre-optic communication subsystem test procedures - Part 4-2:
Installed cabling plant - Single-mode attenuation and optical
return loss measurements
(IEC 61280-4-2:2024)
Procédures d'essai des sous-systèmes de Prüfverfahren für Lichtwellenleiter-
télécommunication fibroniques - Partie 4-2: Installations Kommunikationsuntersysteme - Teil 4-2: Installierte
câblées - Mesures de l'affaiblissement de réflexion optique Kabelanlagen - Einmoden-Dämpfungs- und optische
et de l'affaiblissement des fibres unimodales Rückflussdämpfungsmessung
(IEC 61280-4-2:2024) (IEC 61280-4-2:2024)
This European Standard was approved by CENELEC on 2024-06-10. CENELEC members are bound to comply with the CEN/CENELEC
Internal Regulations which stipulate the conditions for giving this European Standard the status of a national standard without any alteration.
Up-to-date lists and bibliographical references concerning such national standards may be obtained on application to the CEN-CENELEC
Management Centre or to any CENELEC member.
This European Standard exists in three official versions (English, French, German). A version in any other language made by translation
under the responsibility of a CENELEC member into its own language and notified to the CEN-CENELEC Management Centre has the
same status as the official versions.
CENELEC members are the national electrotechnical committees of Austria, Belgium, Bulgaria, Croatia, Cyprus, the Czech Republic,
Denmark, Estonia, Finland, France, Germany, Greece, Hungary, Iceland, Ireland, Italy, Latvia, Lithuania, Luxembourg, Malta, the
Netherlands, Norway, Poland, Portugal, Republic of North Macedonia, Romania, Serbia, Slovakia, Slovenia, Spain, Sweden, Switzerland,
Türkiye and the United Kingdom.
European Committee for Electrotechnical Standardization
Comité Européen de Normalisation Electrotechnique
Europäisches Komitee für Elektrotechnische Normung
CEN-CENELEC Management Centre: Rue de la Science 23, B-1040 Brussels
© 2024 CENELEC All rights of exploitation in any form and by any means reserved worldwide for CENELEC Members.
Ref. No. EN IEC 61280-4-2:2024 E
European foreword
The text of document 86C/1912/FDIS, future edition 3 of IEC 61280-4-2, prepared by SC 86C "Fibre
optic systems and active devices" of IEC/TC 86 "Fibre optics" was submitted to the IEC-CENELEC
parallel vote and approved by CENELEC as EN IEC 61280-4-2:2024.
The following dates are fixed:
• latest date by which the document has to be implemented at national (dop) 2025-03-10
level by publication of an identical national standard or by endorsement
• latest date by which the national standards conflicting with the (dow) 2027-06-10
document have to be withdrawn
This document supersedes EN 61280-4-2:2014 and all of its amendments and corrigenda (if any).
Attention is drawn to the possibility that some of the elements of this document may be the subject of
patent rights. CENELEC shall not be held responsible for identifying any or all such patent rights.
Any feedback and questions on this document should be directed to the users’ national committee. A
complete listing of these bodies can be found on the CENELEC website.
Endorsement notice
The text of the International Standard IEC 61280-4-2:2024 was approved by CENELEC as a
European Standard without any modification.
In the official version, for Bibliography, the following notes have to be added for the standard indicated:
IEC 60793-1-40 NOTE Approved as EN IEC 60793-1-40
IEC 60793-2 NOTE Approved as EN IEC 60793-2
IEC 60793-2-50 NOTE Approved as EN IEC 60793-2-50
IEC 61280-1-3 NOTE Approved as EN IEC 61280-1-3
IEC 61280-4-3:2022 NOTE Approved as EN IEC 61280-4-3:2022 (not modified)
IEC 61280-4-5 NOTE Approved as EN IEC 61280-4-5
IEC 61300-3-4 NOTE Approved as EN IEC 61300-3-4
IEC 61300-3-6 NOTE Approved as EN 61300-3-6
IEC 61745 NOTE Approved as EN 61745
IEC 61753-1 NOTE Approved as EN IEC 61753-1
IEC 61754-19 NOTE Approved as EN 61754-19
IEC 61755-1 NOTE Approved as EN IEC 61755-1
IEC 61755-2-1 NOTE Approved as EN IEC 61755-2-1
IEC 61755-2-2 NOTE Approved as EN IEC 61755-2-2
IEC 61755-2-4 NOTE Approved as EN 61755-2-4
IEC 61755-2-5 NOTE Approved as EN 61755-2-5
Annex ZA
(normative)
Normative references to international publications
with their corresponding European publications
The following documents are referred to in the text in such a way that some or all of their content
constitutes requirements of this document. For dated references, only the edition cited applies. For
undated references, the latest edition of the referenced document (including any amendments)
applies.
NOTE 1 Where an International Publication has been modified by common modifications, indicated by (mod),
the relevant EN/HD applies.
NOTE 2 Up-to-date information on the latest versions of the European Standards listed in this annex is available
here: www.cencenelec.eu.
Publication Year Title EN/HD Year
IEC 60825-2 - Safety of laser products - Part 2: Safety of - -
optical fibre communication systems
(OFCSs)
IEC 61300-3-35 - Fibre optic interconnecting devices and EN IEC 61300-3-35 -
passive components - Basic test and
measurement procedures - Part 3-35:
Examinations and measurements - Visual
inspection of fibre optic connectors and
fibre-stub transceivers
IEC 61315 - Calibration of fibre-optic power meters EN IEC 61315 -
IEC 61746-1 2009 Calibration of optical time-domain EN 61746-1 2011
reflectometers (OTDR) - Part 1: OTDR for
single mode fibres
- - + AC 2014
IEC/TR 62627-01 - Fibre optic interconnecting devices and - -
passive components - Part 01: Fibre optic
connector cleaning methods
IEC 61280-4-2 ®
Edition 3.0 2024-05
INTERNATIONAL
STANDARD
NORME
INTERNATIONALE
Fibre- optic communication subsystem test procedures –
Part 4-2: Installed cabling plant – Single-mode attenuation and optical return
loss measurements
Procédures d’essai des sous-systèmes de télécommunication fibroniques –
Partie 4-2: Installations câblées – Mesures de l'affaiblissement de réflexion
optique et de l'affaiblissement des fibres unimodales
INTERNATIONAL
ELECTROTECHNICAL
COMMISSION
COMMISSION
ELECTROTECHNIQUE
INTERNATIONALE
ICS 33.180.01 ISBN 978-2-8322-8789-7
– 2 – IEC 61280-4-2:2024 © IEC 2024
CONTENTS
FOREWORD . 8
INTRODUCTION . 10
1 Scope . 11
2 Normative references . 11
3 Terms, definitions, graphical symbols and abbreviated terms. 12
3.1 Terms and definitions . 12
3.2 Graphical symbols . 14
3.3 Abbreviated terms . 16
4 Measurement methods . 16
4.1 General . 16
4.1.1 Document structure . 16
4.1.2 Attenuation . 17
4.1.3 Optical return loss . 17
4.2 Cabling configurations and applicable test methods . 18
4.2.1 Cabling configurations and applicable test methods for attenuation
measurements . 18
4.2.2 Cabling configurations and applicable test methods for optical return
loss measurements . 22
5 Overview of uncertainties for attenuation measurements . 22
5.1 General . 22
5.2 Sources of significant uncertainties . 22
5.3 Consideration of the power meter . 22
5.4 Consideration of test cord and connector grade . 23
5.4.1 General . 23
5.4.2 Mode field diameter variation . 23
5.5 Reflections from other interfaces. 23
5.6 Optical source . 24
5.7 Output power reference . 24
5.8 Bi-directional measurements . 24
5.9 Typical uncertainties for attenuation methods A, B, C, and D . 24
5.10 Typical uncertainty values for single-mode attenuation testing for method E . 26
6 Apparatus . 26
6.1 General . 26
6.2 Light source . 26
6.2.1 Stability . 26
6.2.2 Spectral characteristics . 27
6.3 Launch cord . 28
6.4 Receive or tail cords . 28
6.5 Substitution cord . 28
6.6 Power meter – LSPM methods only. 28
6.7 OTDR apparatus . 29
6.8 Return loss test set . 29
6.9 Connector end-face cleaning and inspection equipment . 30
6.10 Adapters . 30
7 Procedures . 31
7.1 General . 31
7.2 Common procedures . 31
IEC 61280-4-2:2024 © IEC 2024 – 3 –
7.2.1 Care of the test cords . 31
7.2.2 Make reference measurements (LSPM and OCWR methods only) . 31
7.2.3 Inspect and clean the ends of the fibres in the cabling . 31
7.2.4 Make the measurements . 32
7.2.5 Make the calculations . 32
7.3 Calibration . 32
7.4 Safety . 32
8 Calculations . 32
9 Documentation . 32
9.1 Information for each test . 32
9.2 Information to be made available . 33
Annex A (normative) One-cord reference method . 34
A.1 Applicability of test method . 34
A.2 Apparatus . 34
A.3 Procedure . 34
A.4 Calculation . 35
A.5 Components of reported attenuation . 36
Annex B (normative) Three-cord reference method . 37
B.1 Applicability of test method . 37
B.2 Apparatus . 37
B.3 Procedure . 37
B.4 Calculations . 38
B.5 Components of reported attenuation . 38
Annex C (normative) Two-cord reference method . 39
C.1 Applicability of test method . 39
C.2 Apparatus . 39
C.3 Procedure . 39
C.4 Calculations . 41
C.5 Components of reported attenuation . 41
Annex D (normative) Equipment cord method . 42
D.1 Applicability of the test method . 42
D.2 Apparatus . 42
D.3 Procedure . 42
D.4 Calculation . 43
D.5 Components of reported attenuation . 44
Annex E (normative) Optical time domain reflectometer . 45
E.1 Applicability of test method . 45
E.2 Apparatus . 45
E.2.1 General . 45
E.2.2 OTDR . 45
E.2.3 Test cords . 45
E.3 Procedure (test method) . 46
E.4 Calculation of attenuation . 47
E.4.1 General . 47
E.4.2 Connection location . 47
E.4.3 Definition of the power levels F and F . 48
1 2
E.4.4 Alternative calculation. 49
E.5 Calculation of optical return loss . 51
– 4 – IEC 61280-4-2:2024 © IEC 2024
E.6 Calculation of reflectance for discrete components . 53
E.7 OTDR uncertainties . 55
Annex F (normative) Continuous wave optical return loss measurement – Method A. 56
F.1 Applicability of test method . 56
F.2 Apparatus . 56
F.2.1 General . 56
F.2.2 Light source . 56
F.2.3 Branching device or coupler . 56
F.2.4 Power meters . 57
F.2.5 Connector interface . 57
F.2.6 Low reflection termination . 57
F.3 Procedure . 57
F.3.1 Test set characterization. 57
F.3.2 Measurement procedure . 59
F.3.3 Calculations . 59
Annex G (normative) Continuous wave optical return loss measurement – Method B . 61
G.1 Applicability of test method . 61
G.2 Apparatus . 61
G.2.1 General requirements . 61
G.2.2 Known reflectance termination . 61
G.3 Procedure . 62
G.3.1 Set-up characterization . 62
G.3.2 Measurement procedure . 62
G.3.3 Calculation . 63
Annex H (normative) On the use of reference-grade test cords . 64
H.1 General . 64
H.2 Practical configurations and assumptions. 64
H.2.1 Component specifications . 64
H.2.2 Conventions . 65
H.2.3 Reference planes . 65
H.3 Impact of using reference-grade test cords for recommended LSPM methods . 66
H.4 Examples for LSPM measurements . 66
H.4.1 Example 1 (configuration A, one-cord method, Annex A) . 66
H.4.2 Example 2 (configuration B, three-cord method, Annex B) . 67
H.4.3 Example 3 (configuration C, two-cord method, Annex C) . 67
H.4.4 Example 4 – Long haul system (one-cord reference method) . 68
H.5 Impact of using reference-grade test cords for different configurations using
the OTDR test method . 68
H.5.1 Cabling configurations A, B and C . 68
H.5.2 Cabling configuration D . 69
Annex I (informative) OTDR configuration information . 71
I.1 Introductory remarks . 71
I.2 Fundamental parameters that define the operational capability of an OTDR . 72
I.2.1 Dynamic range . 72
I.2.2 Dynamic margin . 72
I.2.3 Pulse width . 72
I.2.4 Averaging time . 72
I.2.5 Dead zone . 72
I.3 Other parameters . 73
IEC 61280-4-2:2024 © IEC 2024 – 5 –
I.3.1 Index of refraction . 73
I.3.2 Measurement range . 73
I.3.3 Distance sampling . 73
I.4 Other measurement configurations . 73
I.4.1 General . 73
I.4.2 Macrobend attenuation measurement . 73
I.4.3 Splice attenuation measurement . 74
I.4.4 Measurement with high reflection connectors or short length cabling . 74
I.4.5 Ghost . 76
I.5 More on the measurement method . 77
I.6 Bi-directional measurement . 78
I.7 OTDR bi-directional trace analysis . 79
I.8 Non-recommended practices. 80
I.8.1 Measurement without tail cord . 80
I.8.2 Two cursors measurement . 80
Annex J (informative) Test cord attenuation verification . 81
J.1 Introductory remarks . 81
J.2 Apparatus . 81
J.3 Procedure . 81
J.3.1 General . 81
J.3.2 Test cord verification for the one-cord and two-cord reference test
methods when using non-pinned or unpinned and non-plug or socket
style connectors . 82
J.3.3 Test cord verification for the one-cord and two-cord reference test
methods using pinned-to-unpinned or plug-to-socket style connectors . 83
J.3.4 Test cord verification for the three-cord reference test method using
non-pinned or unpinned and non-plug or socket style connectors . 85
J.3.5 Test cord verification for the three-cord reference test method using
pinned-to-unpinned or plug-to-socket style connectors . 87
Annex K (informative) Spectral attenuation measurement . 89
K.1 Applicability of test method . 89
K.2 Apparatus . 89
K.2.1 Broadband light source . 89
K.2.2 Optical spectrum analyser . 89
K.3 Procedure . 90
K.3.1 Reference scan . 90
K.3.2 Measurement scan . 90
K.4 Calculations . 90
Bibliography . 91
Figure 1 – Connector symbols . 15
Figure 2 – Symbol for cabling under test . 16
Figure 3 – Configuration A – Start and end of measured attenuations in RTM . 19
Figure 4 – Configuration B – Start and end of measured attenuations in RTM . 20
Figure 5 – Configuration C – Start and end of measured attenuations in RTM . 20
Figure 6 – Configuration D – Start and end of measured attenuations in RTM . 21
Figure 7 – Typical OTDR schematic diagram . 29
Figure 8 – Illustration of return loss test set . 30
– 6 – IEC 61280-4-2:2024 © IEC 2024
Figure A.1 – One-cord reference measurement . 35
Figure A.2 – One-cord test measurement . 35
Figure B.1 – Three-cord reference measurement . 37
Figure B.2 – Three-cord test measurement . 38
Figure C.1 – Two-cord reference measurement. 40
Figure C.2 – Two-cord test measurement. 40
Figure C.3 – Two-cord test measurement for plug-to-socket style connectors . 40
Figure D.1 – Reference measurement . 43
Figure D.2 – Test measurement . 43
Figure E.1 – Test measurement for OTDR method . 47
Figure E.2 – Location of the cabling under test ports . 48
Figure E.3 – Graphic construction of F and F . 49
1 2
Figure E.4 – Graphic construction of F , F , F and F . 51
1 11 21 2
Figure E.5 – Graphic representation of OTDR ORL measurement . 53
Figure E.6 – Graphic representation of reflectance measurement . 54
Figure F.1 – Return loss test set illustration . 56
Figure F.2 – Measurement of the system internal attenuation P . 58
ref2
Figure F.3 – Measurement of the system internal attenuation P . 58
ref1
Figure F.4 – Measurement of the system reflected power P . 58
rs
Figure F.5 – Measurement of the input power P . 59
in
Figure F.6 – Measurement of the reflected power P . 59
r
Figure G.1 – Return loss test set illustration . 61
Figure G.2 – Measurement of P with reflections suppressed . 62
rs
Figure G.3 – Measurement of P with reference reflector . 62
ref
Figure G.4 – Measurement of the system reflected power P . 63
rs
Figure G.5 – Measurement of the reflected power P . 63
r
Figure H.1 – Cabling configurations A, B and C tested with the OTDR method . 68
Figure H.2 – Cabling configuration D tested with the OTDR method . 70
Figure I.1 – Splice and macrobend attenuation measurement . 74
Figure I.2 – Attenuation measurement with high reflection connectors . 75
Figure I.3 – Attenuation measurement of a short length cabling . 76
Figure I.4 – OTDR trace with ghost . 77
Figure I.5 – Cursor positioning . 78
Figure I.6 – Bi-directional OTDR trace display . 79
Figure I.7 – Bi-directional OTDR trace attenuation analysis . 80
Figure J.1 – Obtaining reference power level P . 83
Figure J.2 – Obtaining power level P . 83
Figure J.3 – Obtaining reference power level P . 84
Figure J.4 – Obtaining power level P . 84
Figure J.5 – Obtaining reference power level P . 85
IEC 61280-4-2:2024 © IEC 2024 – 7 –
Figure J.6 – Obtaining power level P . 85
Figure J.7 – Obtaining reference power level P . 86
Figure J.8 – Obtaining power level P . 87
Figure J.9 – Obtaining power level P . 87
Figure J.10 – Obtaining reference power level P . 88
Figure J.11 – Obtaining power level P . 88
Figure K.1 – Result of spectral attenuation measurement . 90
Table 1 – Cabling configurations . 18
Table 2 – Test methods and configurations . 21
Table 3 – Test limit adjustment and uncertainty related to test cord connector grade . 23
Table 4 – Uncertainty for given fibre length and attenuation at
1 310 nm, 1 550 nm and 1 625 nm . 25
Table 5 – Uncertainty for a given fibre length at 1 310 nm and 1 550 nm using an
OTDR . 26
Table 6 – Spectral requirements . 27
Table E.1 – Typical launch and tail cord lengths . 46
Table H.1 – Expected attenuation for examples . 65
Table H.2 – Test limit adjustment when using reference-grade test cords . 66
Table H.3 – Test limit adjustment when using reference-grade test cords – OTDR test
method . 69
Table I.1 – Example of effective group index of refraction values . 73
– 8 – IEC 61280-4-2:2024 © IEC 2024
INTERNATIONAL ELECTROTECHNICAL COMMISSION
____________
FIBRE-OPTIC COMMUNICATION SUBSYSTEM TEST PROCEDURES –
Part 4-2: Installed cabling plant –
Single-mode attenuation and optical return loss measurements
FOREWORD
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IEC 61280-4-2 has been prepared by subcommittee 86C: Fibre optic systems and active
devices, of IEC technical committee 86: Fibre optics. It is an International Standard.
This third edition cancels and replaces the second edition published in 2014. This edition
constitutes a technical revision.
This edition includes the following significant technical changes with respect to the previous
edition:
a) addition of the equipment cord method;
b) addition of test limit adjustment related to test cord grades;
c) refinements on measurement uncertainties.
IEC 61280-4-2:2024 © IEC 2024 – 9 –
The text of this International Standard is based on the following documents:
Draft Report on voting
86C/1912/FDIS 86C/1916/RVD
Full information on the voting for its approval can be found in the report on voting indicated in
the above table.
The language used for the development of this International Standard is English.
This document was drafted in accordance with ISO/IEC Directives, Part 2, and developed in
accordance with ISO/IEC Directives, Part 1 and ISO/IEC Directives, IEC Supplement, available
at www.iec.ch/members_experts/refdocs. The main document types developed by IEC are
described in greater detail at www.iec.ch/publications.
A list of all parts in the IEC 61280 series, published under the general title Fibre optic
communication subsystem test procedures, can be found on the IEC website.
The committee has decided that the contents of this document will remain unchanged until the
stability date indicated on the IEC website under webstore.iec.ch in the data related to the
specific document. At this date, the document will be
• reconfirmed,
• withdrawn, or
• revised.
IMPORTANT – The "colour inside" logo on the cover page of this document indicates
that it contains colours which are considered to be useful for the correct understanding
of its contents. Users should therefore print this document using a colour printer.
– 10 – IEC 61280-4-2:2024 © IEC 2024
INTRODUCTION
This document is part of a series of IEC standards for measurements of installed fibre optic
cabling plants. This document is applicabl
...
SIST EN IEC 61280-4-2:2024は、光ファイバー通信サブシステムのテスト手順に関する重要な標準です。この標準の主な焦点は、設置された光ファイバーケーブルプラントにおける単モードの減衰と光戻り損失の測定にあります。この文書は、住宅、商業、産業、データセンター、さらには屋外環境において設置された単モード光ファイバー、コネクタ、アダプタ、スプライスなどを含むあらゆるタイプのケーブルに適用可能です。標準にはIEC 60793-2-50によって指定されたクラスBファイバーを含むあらゆる単モードファイバータイプに対応しています。 本標準の強みは、ケーブルプラントが分岐デバイス(スプリッタ)や特定の波長範囲におけるパッシブ波長選択コンポーネント(WDM、CWDM、DWDMデバイスなど)を含む場合にも適用可能である点です。これにより、多様な設置環境や機器構成においても精度の高い測定が行えます。 また、今回の最新の技術改訂には、機器コード法の追加、試験コードグレードに関する試験限界調整の追加、測定不確かさの精緻化が含まれており、実際の測定プロセスの見直しや改善が図られています。これにより、測定の信頼性と精度が向上しており、業界における標準化の重要性を再確認させられます。 SIST EN IEC 61280-4-2:2024は、光ファイバー通信分野において非常に関連性の高い標準であり、設置された光ファイバーケーブルプラントの品質管理と性能評価において不可欠な役割を果たします。
Le document de normalisation SIST EN IEC 61280-4-2:2024 se concentre sur les procédures d'essai des sous-systèmes de communication par fibres optiques, spécifiquement pour la mesure de l'atténuation et de la perte de retour optique dans des installations de câblage utilisant des fibres monomodes. L’extension de cette norme est particulièrement pertinente pour un large éventail d’utilisations incluant des environnements résidentiels, commerciaux et industriels, ainsi que des centres de données. Parmi les forces notables de cette norme, on trouve son applicability à tous les types de fibres monomodes, incluant celles désignées par la norme IEC 60793-2-50 comme fibres de Classe B. Cela garantit une large utilisation dans divers scénarios d'installation, rendant la norme extrêmement pertinente pour les professionnels du secteur. De plus, la possibilité d'appliquer les principes de cette norme à des installations comprenant des dispositifs de répartition et à des plages de longueurs d'onde spécifiques augmente considérablement son utilité, notamment dans le cas de déploiements impliquant des composants optiques passifs comme les dispositifs WDM, CWDM et DWDM. Les révisions techniques majeures de cette troisième édition, par rapport à l'édition précédente, renforcent également la norme. L'ajout de la méthode du cordon d'équipement et l'ajustement des limites de test en fonction des grades de cordon de test reflètent une réponse aux évolutions technologiques et aux exigences du marché. De plus, les précisions sur les incertitudes de mesure constituent une amélioration significative, augmentant la fiabilité des résultats pour les utilisateurs. La norme SIST EN IEC 61280-4-2:2024, en remplaçant l'édition précédente de 2014, représente donc une avancée significative dans le domaine des tests de câblage de fibres optiques, et est essentielle pour garantir la performance et la conformité des systèmes de communication par fibres optiques. Sa rédaction claire et ses spécifications rigoureuses en font un outil indispensable pour les professionnels du secteur.
SIST EN IEC 61280-4-2:2024는 설치된 광섬유 케이블링 플랜트의 단일 모드 감쇠 및 광학 반사 손실 측정에 대한 국제 표준을 제공하는 중요한 문서입니다. 이 표준의 범위는 단일 모드 광섬유, 커넥터, 어댑터, 스플라이스 및 기타 수동 장치를 포함하는 다양하고 복잡한 케이블링 환경을 포괄합니다. 상업적, 산업적, 주거적 및 데이터 센터 환경 등 다양한 설치 환경에서 적용될 수 있어, 그 유용성은 매우 높습니다. 이 표준의 강점 중 하나는 IEC 60793-2-50에 의해 B 클래스 섬유로 지정된 모든 단일 모드 광섬유 유형에 적용가능하다는 점입니다. 또한, 문서의 원칙은 스플리터와 같은 분기 장치를 포함하는 케이블링 플랜트에도 적용될 수 있으며, WDM, CWDM 및 DWDM 장치와 같은 수동 파장 선택 성분이 배치된 특정 파장 범위에서도 적절하게 이용될 수 있습니다. 이러한 특성은 복잡한 시스템에서도 안정적인 성능 측정을 보장합니다. 2024년 개정판은 2014년에 출판된 두 번째 판을 대체하며, 기술적인 수정이 포함되어 있습니다. 주요 내용으로는 장비 코드 방법의 추가, 테스트 코드 등급과 관련된 테스트 한계 조정, 측정 불확실성에 대한 개선 등이 있습니다. 이러한 변화는 표준의 신뢰성을 높이고, 사용자들이 측정을 수행하는 데 있어 보다 정확하고 일관된 결과를 얻을 수 있도록 합니다. 결론적으로, SIST EN IEC 61280-4-2:2024는 설치된 단일 모드 광섬유 케이블링 플랜트의 성능을 평가하기 위한 필수적인 표준으로, 그 엄격한 측정 프로토콜과 적용범위는 산업 전반에 걸쳐 중요한 역할을 할 것입니다.
Die SIST EN IEC 61280-4-2:2024 ist ein wesentlicher Standard für die Testverfahren von Glasfaserkommunikationssystemen, speziell im Bereich der installierten Verkabelung. Dieser Standard konzentriert sich auf die Messung der Dämpfung und des optischen Rückflussverlusts bei installierten Glasfaserverkabelungsanlagen, die Einzelmodusfasern verwenden. Die Anwendung dieses Standards erstreckt sich über verschiedene Umgebungen, darunter Wohn-, Gewerbe-, Industrie- und Rechenzentren sowie Außenanlagen, was seine Relevanz und Vielseitigkeit unterstreicht. Ein herausragendes Merkmal der SIST EN IEC 61280-4-2:2024 ist die umfassende Abdeckung aller Arten von Einzelmodusfasern, einschließlich der nach IEC 60793-2-50 klassifizierten Fasern der Klasse B. Diese Inklusivität gewährleistet, dass der Standard eine breite Palette von Anwendungen in unterschiedlichen Kontexten abdeckt. Zudem erlauben die in diesem Dokument festgelegten Prinzipien die Anwendung auf Verkabelungssysteme mit Zweigstellenkomponenten und in spezifischen Wellenlängenbereichen, insbesondere wenn passive wellenlängenselektive Komponenten wie WDM-, CWDM- und DWDM-Geräte eingesetzt werden. Die dritte Auflage dieses Dokuments bringt signifikante technische Änderungen mit sich, die einen klaren Fortschritt gegenüber der vorherigen Ausgabe von 2014 darstellen. Dazu gehört die Einführung der Equipment-Cord-Methode, die eine verbesserte Flexibilität bei den Tests ermöglicht. Des Weiteren wurden Anpassungen der Testgrenzwerte in Bezug auf verschiedene Testkabelgrade implementiert, was eine präzisere und spezifischere Messung gewährleistet. Auch die Feinabstimmung der Messunsicherheiten stellt einen wichtigen Schritt zur Verbesserung der Testgenauigkeit dar. Insgesamt zeigt die SIST EN IEC 61280-4-2:2024 nicht nur die Notwendigkeit, die Qualität und Effizienz der optischen Verkabelung zu bestimmen, sondern hebt auch die hohen Standards und technischen Anforderungen hervor, die für moderne Glasfaserkommunikation von zentraler Bedeutung sind.
The SIST EN IEC 61280-4-2:2024 standard provides comprehensive guidelines for measuring single-mode attenuation and optical return loss in installed optical fibre cabling plants. This standard is crucial for professionals in the fibre-optic communication sector, given its wide applicability to various environments such as residential, commercial, industrial, and data centers, as well as outdoor installations. One of the significant strengths of this standard is its inclusivity; it encompasses all types of single-mode fibres, including those specified by IEC 60793-2-50 as Class B fibres. Furthermore, by addressing cabling plants that may include passive devices like connectors and splices, it establishes a broad framework that enhances measurement accuracy across different setups. The recent technical revisions in the 2024 edition, particularly the incorporation of the equipment cord method and adjustments related to test cord grades, represent considerable advancements in measurement accuracy and reliability. Additionally, the inclusion of refinements on measurement uncertainties demonstrates an understanding of the complexities involved in fibre-optic measurements, enabling users to apply these methodologies more effectively. The standard’s emphasis on specific wavelength ranges and devices such as WDM, CWDM, and DWDM further indicates its relevance in modern fibre-optic networks, especially as these technologies become increasingly prevalent. However, it is explicitly noted that this document excludes cabling plants involving active devices, a clear delineation that helps to focus the standard on its intended applications. Overall, SIST EN IEC 61280-4-2:2024 stands out as a critical reference point for professionals tasked with the installation and maintenance of single-mode fibre-optic systems, ensuring that the procedures followed are in line with the latest industry standards and practices. Its practical insights and technical advancements solidify its position as an essential standard in the evolving landscape of fibre-optic communication systems.
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