CLC/TR 50173-99-1:2007

SLOVENSKI STANDARD
01-maj-2008
Vodila polaganja kablov za podporo 10 GBASE-T
Cabling guidelines in support of 10 GBASE-T
Verkabelungsleitfaden zur Unterstützung von 10 GBASE-T
Guide de câblage pour supporter le 10 GBASE-T
Ta slovenski standard je istoveten z: CLC/TR 50173-99-1:2007
ICS:
33.040.50
35.110
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

TECHNICAL REPORT
CLC/TR 50173-99-1
RAPPORT TECHNIQUE
December 2007
TECHNISCHER BERICHT
ICS 35.110
English version
Cabling guidelines in support of 10 GBASE-T

Guide de câblage pour supporter  Verkabelungsleitfaden zur Unterstützung
le 10 GBASE-T von 10 GBASE-T
This Technical Report was approved by CENELEC on 2007-11-02.

CENELEC members are the national electrotechnical committees of Austria, Belgium, Bulgaria, Cyprus, the
Czech Republic, Denmark, Estonia, Finland, France, Germany, Greece, Hungary, Iceland, Ireland, Italy, Latvia,
Lithuania, Luxembourg, Malta, the Netherlands, Norway, Poland, Portugal, Romania, Slovakia, Slovenia, Spain,
Sweden, Switzerland and the United Kingdom.

CENELEC
European Committee for Electrotechnical Standardization
Comité Européen de Normalisation Electrotechnique
Europäisches Komitee für Elektrotechnische Normung

Central Secretariat: rue de Stassart 35, B - 1050 Brussels

© 2007 CENELEC - All rights of exploitation in any form and by any means reserved worldwide for CENELEC members.
Ref. No. CLC/TR 50173-99-1:2007 E

Foreword
This Technical Report was prepared by the Technical Committee CENELEC TC 215, Electrotechnical
aspects of telecommunication equipment.
The text of the draft was submitted to vote and was approved by CENELEC as CLC/TR 50173-99-1
on 2007-11-02.
This Technical Report provides guidance whether an installed generic cabling channel meeting the
requirements of EN 50173-1:2007, Class E, will support 10 GBASE-T as specified by IEEE 802.3an.
The Technical Report also provides mitigation procedures to improve the performance of Class E
channels to the point where the application is supported. Generic cabling channels meeting the
requirements of EN 50173-1:2007, Class F, will support IEEE 802.3an up to 100 m without mitigation.
The support of IEEE 802.3an includes additional parameters and an extended frequency range
beyond Class E. Conformance of installed cabling beyond the original cabling specifications must be
determined on a case-by-case basis, and is primarily needed due to new external noise requirements.
Whether these requirements are met by a specific channel is influenced by the components and
installation practices used. As IEEE 802.3an uses frequencies above those specified for Class E of
EN 50173-1:2007, input from supplier and installer may be helpful to evaluate the performance of
installed Class E channels.
This Technical Report takes into account the design goals for IEEE 802.3an (10 GBASE-T) equipment
such as:
a) frequency signal range up to 500 MHz;
b) meet EMC limits specified for EN 55022:2006, Class A;
NOTE While IEEE 802.3an specifies an application to meet Class A on unshielded cabling, meeting Class B may require
application specific equipment and/or cabling that exceeds the requirements of this TR respectively.
–12
c) support a bit error rate of 10 ;
d) support operation over four-connector, four-pair balanced cabling.
It is expected that IEEE 802.3an will be supported by the following cabling channels specified in
EN 50173-1:2007:
– Class F channels will support IEEE 802.3an to distances of at least 100 m;
– Class E channels using screened Category 6 components and assessed and mitigated according
to the guidelines in this Technical Report will support IEEE 802.3an over distances up to 100 m;
– Class E channels assessed and mitigated according to the guidelines in this Technical Report are
expected to support IEEE 802.3an over distances from 55 m up to 100 m using unscreened
Category 6 components.
In order to provide normative cabling specifications in explicit support of IEEE 802.3an, an amendment
to EN 50173-1:2007 is under consideration. This amendment will provide new channel specifications
that will include all characteristics needed to meet and/or exceed the IEEE 802.3an requirements
(Class E and Class F ).
A A
This Technical Report is derived from ISO/IEC TR 24750, which has been developed by
ISO/IEC JTC 1/SC 25 as a Technical Report Type 2.

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Contents
Introduction. 5
1 Scope. 7
2 Normative references . 7

3 Definitions and abbreviations. 7
3.1 Definitions . 7
3.2 Abbreviations. 9

4 Channel requirements. 9
4.1 General . 9

4.2 Return loss.10
4.3 Insertion loss .10
4.4 Near-end crosstalk loss (NEXT).11
4.5 Attenuation to crosstalk loss ratio near-end (ACR-N) .13
4.6 Attenuation to crosstalk loss ratio far-end (ACR-F).14
4.7 Alien (exogenous) crosstalk.16
4.8 Propagation delay.21
4.9 Delay skew.21
5 Guidance for mitigation.21
5.1 Planning certification, measurement and documentation.21
5.2 Mitigation techniques if in-channel parameters of the channel
from Clause 4 are not met .22
5.3 Mitigation techniques in case external parameters
of the channel (alien noise) from 4.7 are not met.22

Annex A (informative) Permanent link performance guidelines.24
Annex B (normative) Alien crosstalk margin computation.26

Annex C (informative) Analytical approach to alien crosstalk mitigation .31
Tables
Table 1 – Changes and additions to definitions in EN 50173-1:2007. 6
Table 2 – Equations for return loss limits for a channel .10
Table 3 – Return loss limits for a channel at key frequencies .10
Table 4 – Equation for insertion loss limits for a channel.11
Table 5 – Insertion loss limits for a channel at key frequencies .11
Table 6 – Equations for NEXT limits for a channel .11
Table 7 – NEXT limits for a channel at key frequencies .11
Table 8 – Equations for PSNEXT limits for a channel.12
Table 9 – PSNEXT limits for a channel at key frequencies.12
Table 10 – ACR-N limits for a channel at key frequencies.13

Table 11 – PSACR-N limits for a channel at key frequencies .14
Table 12 – Equation for ACR-F limits for a channel.15
Table 13 – ACR-F limits for a channel at key frequencies .15
Table 14 – Equation for PSACR-F limits for a channel.15

Table 15 – PSACR-F limits for a channel at key frequencies.16
Table 16 – Equations for PSANEXT limits for a channel .17
Table 17 – PSANEXT limits for a channel at key frequencies.17
Table 18 – Equations for PSAACR-F limits for a channel.19
Table 19 – PSAACR-F limits for a channel at key frequencies and lengths .20

Table 20 – Examples of implementations at key insertion loss .20
Table 21 – Equations for propagation delay limits for a channel.21
Table 22 – Propagation delay limits for a channel at key frequencies.21
Table 23 – Delay skew limits for a channel .21
Table A.1 – Return loss for permanent link .24
Table A.2 – Insertion loss for permanent link .24
Table A.3 – NEXT for permanent link .25
Table A.4 – PSNEXT for permanent link.25
Table A.5 – ACR-F for permanent link .25
Table A.6 – PSACR-F for permanent link .25
Table B.1 – Power backoff schedule from main body IEEE 802.3 10 GBASE-T .26

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Introduction
In order to support IEEE 802.3 10 GBASE-T (ISO/IEC 8802-3:2000/A1, at present draft) over a
generic cabling systems as defined in series EN 50173, several new parameters are required to
specify the electrical transmission properties of the channel.
EN 50173-1 defines ACR and ELFEXT as: The S/N ratio of the noise in the disturbed pair to the signal
in the disturbing pair. The definition in EN 50173-1 is correct for cabling.
IEEE 802.3an defines these parameters slightly different: The S/N ratio of the noise in the disturbed
pair to the signal in the disturbed pair. This is of course the definition of importance for electrical
systems.
For equally long channels the values of both definitions are nearly the same, but if the channels have
different length the values based on IEEE 802.3an and EN 50173-1:2007 are different.
To align with IEEE 802.3an it was decided in February 2006 to change the naming and definition in
their cabling standard of some noise related items. The limits stay the same so backward compatibility
is assured (see Table 1 for summary).
Crosstalk and power sum crosstalk are well defined in EN 50173-1:2007. As cables are laid in trays,
ducts and/or are bundled together, the noise from one cable can couple into other cables. This can
happen between telecommunications cables of the same category, but also between cables with
different categories or even between signal or power line cables and telecommunications cables.
This type of noise is well known in telephony and existing versions of Ethernet over balanced cabling.
It has not been a major issue for the systems in use up to now. However, the increased frequency
range and sensitivity of the IEEE 802.3an transmission cannot neglect this external noise any more.
Only the power sum of the noise is of importance and is specified because it is irrelevant from which
external pairs or cables the noise is coming from and the noise from external sources cannot be
compensated for within the specific application addressed here. The power sum computation assumes
that the noise is generated by other channels using the same protocol. Disturbances that are created
by other protocols (like TV distribution) using the other channels are handled as background noise. To
determine alien crosstalk noise, the transmitter must therefore be known.
In a channel as specified in EN 50173-1, and measured in accordance with EN 50346, the near-end
(where the measurement transmitter is) and the far-end (were the measurement receiver is) are
known and the terms NEXT and FEXT are easy to define.
For alien crosstalk the term ANEXT or AFEXT can be ambiguous. Therefore new definitions for power
sum alien crosstalk noise (near-end and far-end) are introduced (see definitions). It appears that the
worst case situation is when a short channel runs in parallel at either end of a long channel. The short
channel with high signals will disturb the long channel receiver where receiving signals have been
attenuated due to the insertion loss of the long channel. For this case IEEE 802.3an introduced power
backoff strategies. The idea is that a system detects the length of the
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