SIST EN 50173-1:2008/A1:2010

SLOVENSKI STANDARD
SIST EN 50173-1:2008/A1:2010
01-marec-2010
Informacijska tehnologija - Univerzalni sistemi polaganja kablov - 1. del: Splošne
zahteve
Information technology - Generic cabling systems -- Part 1: General requirements
Informationstechnik - Anwendungsneutrale Kommunikationskabelanlagen -- Teil 1:
Allgemeine Anforderungen
Technologies de l'information - Systèmes de câblage générique -- Partie 1: Exigences
générales
Ta slovenski standard je istoveten z: EN 50173-1:2007/A1:2009
ICS:
33.040.50 Vodi, zveze in tokokrogi Lines, connections and
circuits
35.110 Omreževanje Networking
SIST EN 50173-1:2008/A1:2010 en,fr,de
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

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SIST EN 50173-1:2008/A1:2010

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SIST EN 50173-1:2008/A1:2010

EUROPEAN STANDARD
EN 50173-1/A1

NORME EUROPÉENNE
November 2009
EUROPÄISCHE NORM

ICS 33.040.50


English version


Information technology -
Generic cabling systems -
Part 1: General requirements



Technologies de l'information -  Informationstechnik -
Systèmes de câblage générique - Anwendungsneutrale
Partie 1: Exigences générales Kommunikationskabelanlagen -
Teil 1: Allgemeine Anforderungen




This amendment A1 modifies the European Standard EN 50173-1:2007; it was approved by CENELEC on
2009-09-01. CENELEC members are bound to comply with the CEN/CENELEC Internal Regulations which
stipulate the conditions for giving this amendment 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 Central Secretariat or to any CENELEC member.

This amendment 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
Central Secretariat has the same status as the official versions.

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: Avenue Marnix 17, B - 1000 Brussels


© 2009 CENELEC - All rights of exploitation in any form and by any means reserved worldwide for CENELEC members.
Ref. No. EN 50173-1:2007/A1:2009 E

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SIST EN 50173-1:2008/A1:2010
EN 50173-1:2007/A1:2009 - 2 -

Foreword
This amendment was prepared by the Technical Committee CENELEC TC 215, Electrotechnical aspects of
telecommunication equipment.
The text of the draft was submitted to the formal vote and was approved by CENELEC as amendment A1 to
EN 50173-1:2007 on 2009-09-01.
The following dates were fixed:
– latest date by which the amendment has to be implemented
at national level by publication of an identical
national standard or by endorsement (dop) 2010-09-01
– latest date by which the national standards conflicting
with the amendment have to be withdrawn (dow) 2012-09-01
This amendment introduces, among others, new Class E and F channels, resulting in an amendment of
A A
many tables in Clause 5. Furthermore some specifications for BCT applications for residential cabling have
been modified.
__________

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Introduction
Replace Figure 1 by:
EENN 50098-50098-1:1: C Cuussttoommerer p prreemmiisseess EENN 501 50173-73-2:2: I Innffoormrmaattiioonn t teecchnolhnologogyy::
ccablabliinng fg foorr i innffoormrmatatiion ton teecchhnonollogyogy - - GGenereneriicc c cablabliing -ng - OOffffiiccee prpreemmiisseess
IISSDDNN b baassiicc a acceccessss
EENN 5017 50173-3-3:3: I Innffoorrmmatatiion ton teecchhnnoollogyogy::
EENN 50 50098-098-2:2: C Cuussttoommeerr pr preemmiisseses GGeenerneriicc c cablabliinng -g - IIndusndusttrriiaall pr prememiisseess
EENN 50173 50173--11:: IInnffoorrmmatatiion ton teecchhnnoollogyogy::
ccablabliing ng ffoorr i innffoorrmmatatiion ton teecchhnolnologyogy - -
EENN 50173- 50173-4:4: I Innffoorrmmatatiion ton teecchnolhnologyogy:: GGeenerneriicc c cablabliinngg - - GGeenerneralal r requiequirreemmententss
2048 2048 kkbbiitt//ss IISSDDNN p prriimmararyy a acccceessss and and
GGeneenerriicc c cablabliing ng -- HHomomeses
lleeasased led liine nne neettwwoorrkk i inntteerrffacacee
EENN 5 50173-0173-5:5: I Innffoorrmmatatiion ton teecchnolhnologogyy::
GGenereneriicc c cablabliing -ng - DDaatta ca cententrreess
EENN 5017 50174-4-11:: I Innffoorrmmatatiion ton teecchhnnoollooggyy – – EENN 50310 50310:: A Applppliiccatatiion ofon of e equiquipotpotententiiaall
bbondionding and eng and eaarrtthhiingng iinn b buuiillddiingsngs w wiitthh
CCablabliing ing innssttalalllaattiion –on – IInsnsttaallllaattiioonn
iinnffoorrmmatatiion ton teecchhnolnologogyy equiequipmpmentent
ssppececiiffiiccatatiion anon and qd qualualiittyy as asssuurrancancee
EENN 501 50174-74-2:2: I Innffoormrmaattiioonn t teecchnolhnologogyy - -
CCablabliing ing innssttalalllaattiionon - - IInnssttaallllaattiion on
plplananniningng and pr and pracacttiicceess i innssiide bde buuiilldidinnggss
EENN 501 50174-74-3:3: I Innffoormrmaattiioonn t teecchnolhnologogyy - -
CCablabliing ing innssttalalllaattiionon - - IInnssttaallllaattiion on
plplananniningng and pr and pracacttiicceess out outssiide bde buuiillddiingsngs
EENN 50 50346:346: I Innffoorrmmatatiion ton teecchhnolnologogyy --
CCaabblliing ing innssttalalllaattiionon - -
TTeessttiing ng ofof i innssttalallled ced cablabliinngg

NOTE CLC/TC 215 has also produced a Technical Report CLC/TR 50173-99-1 “Cabling guidelines in support of 10 GBASE-T”.
Figure 1 – Schematic relationship between the EN 50173 series and other relevant standards

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Replace Table 1 by:
Table 1 – Contextual relationship between EN 50173 series and other relevant standards
Building design phase Generic cabling Specification phase Installation phase Operation phase
design phase
EN 50310 EN 50173 series EN 50174-1 EN 50174-1
except
EN 50173-4
5.2: Common bonding 4: Structure 4: Requirements for 4: Requirements for
network (CBN) within a specifying installations specifying installations
5: Channel performance
building of information of information
technology cabling technology cabling
7: Cable requirements
6.3: AC distribution
system and bonding of 5: Requirements for
8: Connecting hardware
the protective conductor installers of information
requirements
(TN-S) technology cabling
9: Requirements for

cords and jumpers
A: Link performance
limits
 Planning phase
and
EN 50173-4 EN 50174-2 EN 50174-2
4 and 5: Structure 4: Requirements for 5: Requirements for the
planning installations of installation of
6: Channel performance
information technology information technology
cabling cabling
8: Cable requirements
6: Segregation of 6: Segregation of
9: Connecting hardware
metallic information metallic information
requirements
technology cabling and technology cabling and
10: Requirements for mains power cabling mains power cabling
cords and jumpers
7: Electricity distribution
A: Link performance
systems and lightning
limits
protection
 and and
EN 50174-3 EN 50174-3
 and and
(for equipotential (for equipotential
bonding) bonding)
EN 50310 EN 50310
 5.2: Common bonding 5.2: Common bonding
network (CBN) within a network (CBN) within a
building building
6.3: AC distribution 6.3: AC distribution
system and bonding of system and bonding of
the protective conductor the protective conductor
(TN-S) (TN-S)
  and
EN 50346
  4: General requirements
5: Test parameters for
balanced cabling
6: Test parameters for
optical fibre cabling

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2 Normative references
Replace EN 61196-3 by:
EN 50117-4-1, Coaxial cables – Part 4-1: Sectional specification for cables for BCT cabling in accordance
with EN 50173 – Indoor drop cables for systems operating at 5 MHz - 3 000 MHz
Amend EN 60793-2-10 to read:
EN 60793-2-10:2007, Optical fibres – Part 2-10: Product specifications – Sectional specification for category
A1 multimode fibres (IEC 60793-2-10:2007)
Add the following reference:
CLC/TR 50173-99-1, Cabling guidelines in support of 10 GBASE-T
3.1 Definitions
Add the following definitions and renumber the existing definitions accordingly:
3.1.2
alien (exogenous) crosstalk
signal coupling from a disturbing pair of a channel to a disturbed pair of another channel
NOTE This also applies to the signal coupling from a disturbing pair within a permanent link or component, used to create a channel,
to a disturbed pair within a permanent link or component, used to create another channel.
3.1.3
alien (exogenous) far-end crosstalk loss (AFEXT)
signal isolation between a disturbing pair of a channel and a disturbed pair of another channel, measured at
the far-end
NOTE This also applies to the measurement of the signal isolation between a disturbing pair within a permanent link or component,
used to create a channel, and a disturbed pair within a permanent link or component, used to create another channel.
3.1.4
alien (exogenous) near-end crosstalk loss (ANEXT)
signal isolation between a disturbing pair of a channel and a disturbed pair of another channel, measured at
the near-end
NOTE This also applies to the measurement of the signal isolation between a disturbing pair within a permanent link or component,
used to create a channel, and a disturbed pair within a permanent link or component, used to create another channel.
Renumber existing definition 3.1.2 into 3.1.5.
3.1.6
attenuation to alien (exogenous) crosstalk ratio at the far-end (AACR-F)
difference, in dB, between the alien far-end crosstalk loss from a disturbing pair of a channel and the
insertion loss of a disturbed pair in another channel
NOTE This also applies to the calculation using the alien far-end crosstalk loss from a disturbing pair within a permanent link or
component, used to create a channel, and the insertion loss of a disturbed pair within a permanent link or component, used to create
another channel.
3.1.7
attenuation to alien (exogenous) crosstalk ratio at the near-end (AACR-N)
difference, in dB, between the alien near-end crosstalk loss from a disturbing pair of a channel and the
insertion loss of a disturbed pair in another channel
NOTE This also applies to the calculation using the alien near-end crosstalk loss from a disturbing pair within a permanent link or
component, used to create a channel, and the insertion loss of a disturbed pair within a permanent link or component, used to create
another channel.

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3.1.8
attenuation to crosstalk ratio at the far-end (ACR-F)
difference, in dB, between the far-end crosstalk loss from a disturbing pair of a channel and the insertion loss
of a disturbed pair of the same channel
NOTE This also applies to the calculation using the far-end crosstalk loss from a disturbing pair within a permanent link or
component, used to create a channel, and the insertion loss of a disturbed pair within the permanent link or component, of the same
channel.
3.1.9
attenuation to crosstalk ratio at the near-end (ACR-N)
difference, in dB, between the near-end crosstalk loss from a disturbing pair of a channel and the insertion
loss of a disturbed pair of the same channel
NOTE This also applies to the calculation using the near-end crosstalk loss from a disturbing pair within a permanent link or
component, used to create a channel, and the insertion loss of a disturbed pair within the permanent link or component, of the same
channel.
3.1.10
average alien (exogenous) near-end crosstalk loss
calculated average of the alien near-end crosstalk loss of the pairs of a disturbed channel
NOTE This also applies to the calculation using the pairs within a permanent link, used to create a channel.
3.1.11
average power sum alien (exogenous) near-end crosstalk loss
calculated average of the power sum alien near-end crosstalk loss of the pairs of a disturbed channel
NOTE This also applies to the calculation using the pairs within a permanent link used to create a channel.
3.1.12
average power sum attenuation to alien (exogenous) crosstalk ratio far-end
calculated average of the power sum attenuation to alien crosstalk ratio at the far-end of the pairs of a
disturbed channel
NOTE This also applies to the calculation using the pairs within a permanent link used to create a channel.
Renumber existing definitions 3.1.3 to 3.1.46 into 3.1.13 to 3.1.56.
Replace definition 3.1.7 (renumbered 3.1.17) by:
3.1.17
building entrance facility
space that provides all necessary mechanical and electrical services for the entry of cables into a building
Replace definition 3.1.26 (renumbered 3.1.36) by:
3.1.36
external network interface
termination point providing external network demarcation
Add the following definitions and renumber the existing definitions 3.1.47 to 3.1.56 into 3.1.63 to 3.1.72 :
3.1.57
power sum alien (exogenous) far-end crosstalk loss (PSAFEXT)
power sum of the signal isolation between multiple disturbing pairs of one or more channels and a disturbed
pair of another channel, measured at the far-end
NOTE This also applies to the calculation using the multiple disturbing pairs within one or more permanent links or components and
a disturbed pair within a permanent link or component, used to create another channel.

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3.1.58
power sum alien (exogenous) near-end crosstalk loss (PSANEXT)
power sum of the signal isolation between multiple disturbing pairs of one or more channels and a disturbed
pair of another channel, measured at the near-end
NOTE This also applies to the calculation using the multiple disturbing pairs within one or more permanent links or components and
a disturbed pair within a permanent link or component, used to create another channel.
3.1.59
power sum attenuation to alien (exogenous) crosstalk ratio at the far-end (PSAACR-F)
difference, in dB, between the power sum alien far-end crosstalk loss from multiple disturbing pairs of one or
more channels and the insertion loss of a disturbed pair in another channel
NOTE This also applies to the calculation using the multiple disturbing pairs within one or more permanent links or components and
the insertion loss of a disturbed pair within a permanent link or component, used to create another channel.
3.1.60
power sum attenuation to alien (exogenous) crosstalk ratio at the near-end (PSAACR-N)
difference, in dB, between the power sum alien near-end crosstalk loss from multiple disturbing pairs of one
or more channels and the insertion loss of a disturbed pair in another channel
NOTE This also applies to the calculation using the multiple disturbing pairs within one or more permanent links or components and
the insertion loss of a disturbed pair within a permanent link or component, used to create another channel.
3.1.61
power sum attenuation to crosstalk ratio at the far-end (PSACR-F)
difference, in dB, between the power sum far-end crosstalk loss from multiple disturbing pairs of a channel
and the insertion loss of a disturbed pair in the same channel
NOTE This also applies to the calculation using the multiple disturbing pairs within one or more permanent links or components,
used to create a channel, and the insertion loss of a disturbed pair within a permanent link or component, of the same channel.
3.1.62
power sum attenuation to crosstalk ratio at the near-end (PSACR-N)
difference, in dB, between the power sum near-end crosstalk loss from multiple disturbing pairs of a channel
and the insertion loss of a disturbed pair in the same channel
NOTE This also applies to the calculation using the multiple disturbing pairs within one or more permanent links or components,
used to create a channel, and the insertion loss of a disturbed pair within a permanent link or component, of the same channel.
3.2 Abbreviations
Replace ACR and PSACR by:
ACR-N Attenuation to crosstalk ratio at the near-end
PSACR-N Power sum attenuation to crosstalk ratio at the near-end
Delete ELFEXT and PSELFEXT.
Add the following abbreviations:
AACR-F Attenuation to alien (exogenous) crosstalk ratio at the far-end
ACR-F Attenuation to crosstalk ratio at the far-end
AFEXT Alien (exogenous) far-end crosstalk loss
ANEXT Alien (exogenous) near-end crosstalk loss
FEXT Far-end crosstalk loss

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Insertion loss
α
Average insertion loss
α
avg
PSAACR-F Power sum attenuation to alien (exogenous) crosstalk ratio at the far-end
PSAACR-F Average power sum attenuation to alien (exogenous) crosstalk ratio at the far-end
avg
PSACR-F Power sum attenuation to crosstalk ratio at the far-end
PSAFEXT Power sum alien (exogenous) far-end crosstalk loss
PSAFEXT Normalised power sum alien (exogenous) far-end crosstalk loss
norm
PSANEXT Power sum alien (exogenous) near-end crosstalk loss
PSANEXT Average power sum alien (exogenous) near-end crosstalk loss
avg
5.2.2.1 General
st nd
Replace the 1 and 2 paragraphs by:
This standard specifies the following classes for balanced cabling:
a) Class A: specified up to 0,1 MHz;
b) Class B: specified up to 1 MHz;
c) Class C: specified up to 16 MHz;
d) Class D: specified up to 100 MHz;
e) Class E: specified up to 250 MHz;
f) Class E : specified up to 500 MHz;
A
g) Class F: specified up to 600 MHz;
h) Class F : specified up to 1 000 MHz.
A
A Class A channel is specified so that it will provide the minimum transmission performance to support
Class A applications. Similarly, Class B, C, D, E, E , F and F channels provide the transmission
A A
performance to support Class B, C, D, E, E , F and F applications respectively. Channels of a given class
A A
will support all applications of a lower class. Class A is regarded as the lowest class.
5.2.2.2 Return loss
st
Replace the 1 paragraph by:
The variation of the input impedance of a channel is characterised by the return loss. The return loss
parameter is applicable to Classes C, D, E, E , F, F and BCT-B only. The return loss for each pair of a
A A
channel shall meet the limits computed, to one decimal place, using the formulae of Table 4. The limits
shown in Table 5 are derived from the formulae at key frequencies only.

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Replace Table 4 and Table 5 by:
Table 4 – Formulae for return loss limits for a channel
Class Frequency Minimum return loss
MHz dB
C 1 ≤ f ≤16 15,0
1 ≤ f < 20 17,0
D
30−×10 lg f
20 ≤ f ≤ 100
19,0
1 ≤ f < 10
24−×5 lg f
10 ≤ f < 40
E
32−×10 lg f
40 ≤ f ≤ 250
19,0
1 ≤ f < 10
24−×5 lg f
10 ≤ f < 40
E
A
32−×10 lg f
40 ≤ f < 398,1
398,1 ≤ f ≤ 500 6,0
1 ≤ f < 10 19,0
24−×5 lg f
10 ≤ f < 40
F
32−×10 lg f
40 ≤ f < 251,2
251,2 ≤ f ≤ 600 8,0
19,0
1 ≤ f < 10
24−×5 lg f
10 ≤ f < 40
32−×10 lg f
F 40 ≤ f < 251,2
A
8,0
251,2 ≤ f < 631
36−×10 lg f
631 ≤ f ≤ 1 000
19,0
4 ≤ f < 10
10 ≤ f < 100 24−×5 lg f
100 ≤ f < 251,2 29−×7,5 lg f
BCT-B
251,2 ≤ f < 600 17,2−×2,6 lg f
600 ≤ f ≤ 1 000 35−×9 lg f

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Table 5 – Return loss limits for a channel at key frequencies
Minimum return loss
dB
Frequency 0,1 1,0 16,0 100,0 250,0 500,0 600,0 1 000,0
MHz
Class C N/A 15,0 15,0 N/A N/A N/A N/A N/A
Class D N/A 17,0 17,0 10,0 N/A N/A N/A N/A
Class E N/A 19,0 18,0 12,0 8,0 N/A N/A N/A
Class E N/A 19,0 18,0 12,0 8,0 6,0 N/A N/A
A
Class F N/A 19,0 18,0 12,0 8,0 8,0 8,0 N/A
Class F N/A 19,0 18,0 12,0 8,0 8,0 8,0 6,0
A
Class BCT-B N/A 19,0 18,0 14,0 11,0 10,2 10,0 8,0
5.2.2.3 Insertion loss
Replace Table 6 and Table 7 by:
Table 6 – Formulae for insertion loss limits for a channel
Class Frequency Maximum insertion loss
MHz dB
A f = 0,1 16,0
f = 0,1
5,5
B
f = 1 5,8
C 1,05××3,23 f + 4× 0,2
1 ≤ f ≤ 16 ()
D 1,05××1,910 8ff+ 0,022 2×+ 0,2f + 4× 0,04×f , 4,0 min.
1 ≤ f ≤ 100 ()
E 1 ≤ f ≤ 250 1,05××1,82ff+ 0,016 9×+ 0,25f+ 4× 0,02×f , 4,0 min.
()
E 1 ≤ f ≤ 500 1,05××1,82ff+ 0,009 1×+ 0,25f+ 4× 0,02×f , 4,0 min.
A ()
1,05××1,8ff+ 0,01× + 0,2f+ 4× 0,02×f , 4,0 min.
F 1 ≤ f ≤ 600 ()
1,05××1,8ff+ 0,005× + 0,25f+ 4× 0,02×f , 4,0 min.
F 1 ≤ f ≤ 1 000 ()
A
CCCB f = 0,1 4,0
BCT-B-L 1 ≤ f ≤ 1 000 0,132××1,645ff+0,01×+0,25f+2×0,02 2,×f ,0min.
()
BCT-B-M 1 ≤ f ≤ 1 000 0,264××1,645ff+0,01 0,×+25f+2×0,02×f ,2,0min.
()
0,514××1,645 0ff+,01×+0,25f+2 ×0,02×f ,2,0min.
BCT-B-H 1 ≤ f ≤ 1 000 ()
NOTE The slope (difference in attenuation) between 47 MHz and 862 MHz is critical for BCT- B applications.
See F.1 for additional information regarding supported applications.

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Table 7 – Insertion loss limits for a channel at key frequencies
Maximum insertion loss
dB
Frequency 0,1 1,0 16,0 100,0 250,0 500,0 600,0 1 000,0
MHz
Class A 16,0 N/A N/A N/A N/A N/A N/A N/A
Class B 5,5 5,8 N/A N/A N/A N/A N/A N/A
Class C N/A 4,2 14,4 N/A N/A N/A N/A N/A
Class D N/A 4,0 9,1 24,0 N/A N/A N/A N/A
Class E N/A 4,0 8,3 21,7 35,9 N/A N/A N/A
Class E N/A 4,0 8,2 20,9 33,9 49,3 N/A N/A
A
Class F N/A 4,0 8,1 20,8 33,8 49,3 54,6 N/A
Class F N/A 4,0 8,0 20,3 32,5 46,7 51,4 67,6
A
Class CCCB 4,0 N/A N/A N/A N/A N/A N/A N/A
Class BCT-B-L N/A 2,0 2,0 2,7 4,4 6,4 7,1 9,5
Class BCT-B-M N/A 2,0 2,0 5,0 8,2 11,9 13,2 17,6
Class BCT-B-H N/A 2,0 3,7 9,4 15,3 22,4 24,8 33,2
5.2.2.4.1 Pair-to-pair NEXT
st
Replace the 1 paragraph by:
The pair-to-pair NEXT parameter is applicable to Classes A to F . The pair-to-pair NEXT α for each pair
A NEXT
combination of a channel shall meet the limits computed, to one decimal place, using the formulae of
Table 8. The limits shown in Table 9 are derived from the formulae at key frequencies only.

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Replace Table 8 and Table 9 by:
Table 8 – Formulae for NEXT limits for a channel
Class Frequency Minimum NEXT
MHz dB
A f = 0,1 27,0
B 0,1 ≤ f ≤ 1 25−×15 lg f
C 39,1−×16,4 lg f
1 ≤ f ≤ 16
65,3−×15 lg f 83− 20× lg f


−−20 20
D −×20 lg 10 + 2× 10 , 65,0 max.
1 ≤ f ≤ 100


74,3−×15lgff94−20l×g


−−20 20
E 1 ≤ f ≤ 250 −×20 lg 10 + 2× 10 , 65,0 max


74,3−×15 lg f 94− 20× lg f

a, c
−−20 20
E −×20 lg 10 + 2× 10 , 65,0 max
A 1 ≤ f ≤ 500


102,4−×15 lg f 102,4−×15 lg f


−−20 20
F −×20 lg 10 + 2× 10 , 65,0 max.
1 ≤ f ≤ 600


105,4−×15 lgff116,3− 20× lg

b, c

−−20 20
F 1 ≤ f ≤ 1 000 −×20 lg 10 + 2× 10 , 65,0 max.
A


a
Where the channel insertion loss at 450 MHz is less than 12 dB, the requirement is reduced by
1,4((f – 450)/50) for f ≥ 450 MHz.
b
Where the channel insertion loss at 900 MHz is less than 17 dB, the requirement is reduced by

2,8((f – 900)/100) for f ≥ 900 MHz.
c
The terms in the formulae are not intended to imply component performance.
Table 9 – NEXT limits for a channel at key frequencies
Minimum NEXT
dB
Frequency 0,1 1,0 16,0 100,0 250,0 500,0 600,0 1 000,0
MHz
Class A 27,0 N/A N/A N/A N/A N/A N/A N/A
Class B 40,0 25,0 N/A N/A N/A N/A N/A N/A
Class C N/A 39,1 19,4 N/A N/A N/A N/A N/A
Class D N/A 63,3 43,6 30,1 N/A N/A N/A N/A
Class E N/A 65,0 53,2 39,9 33,1 N/A N/A N/A
Class E N/A 65,0 53,2 39,9 33,1 27,9 N/A N/A
A
Class F N/A 65,0 65,0 62,9 56,9 52,4 51,2 N/A
Class F N/A 65,0 65,0 65,0 59,1 53,6 52,1 47,9
A

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SIST EN 50173-1:2008/A1:2010
- 13 - EN 50173-1:2007/A1:2009

5.2.2.4.2 Power sum NEXT (PSNEXT)
st
Replace the 1 paragraph by:
The PSNEXT parameter is applicable to Classes D, E, E , F and F only. The PSNEXT α for each pair
A A PSNEXT
of a channel shall meet the limits computed, to one decimal place, using the formulae of Table 10. The limits
shown in Table 11 are derived from the formulae at key frequencies only.
Replace Table 10 and Table 11 by:
Table 10 – Formulae for PSNEXT limits for a channel
Class Frequency Minimum PSNEXT
MHz dB
62,3−×15 lgff80− 20×l g

−−20 20
D 1 ≤ f ≤ 100 −×20 lg 10 + 2× 10 , 62,0 max.


72,3−×15 lgff90− 20× lg


−−20 20
E −×20 lg 10 + 2× 10 , 62,0 max
1 ≤ f ≤ 250


72,3−×15 lgff90− 20× lg

a, c

−−20 20
E −×20 lg 10 + 2× 10 , 62,0 max
A 1 ≤ f ≤ 500


99,4−×15 lgf,99 4−×15 lgf

−−20 20
F −×20 lg 10 + 2× 10 , 62,0 max.
1 ≤ f ≤ 600


102,4−×15 lgff113,3− 20× lg

b, c

−−20 20
F −×20 lg 10 + 2× 10 , 62,0 max.
A 1 ≤ f ≤ 1 000


a
Where the channel insertion loss at 450 MHz is less than 12 dB, the requirement is reduced by
1,4((f – 450)/50) for f ≥ 450 MHz.
b
Where the channel insertion loss at 900 MHz is less than 17 dB, the requirement is reduced by

2,8((f – 900)/100) for f ≥ 900 MHz.
c
The terms in the formulae are not intended to imply component performance.
Table 11 – PSNEXT limits for a channel at key frequencies
Minimum PSNEXT
dB
Frequency 0,1 1,0 16,0 100,0 250,0 500,0 600,0 1 000,0
MHz
Class D N/A 60,3 40,6 27,1 N/A N/A N/A N/A
Class E N/A 62,0 50,6 37,1 30,2 N/A N/A N/A
Class E N/A 62,0 50,6 37,1 30,2 24,8 N/A N/A
A
Class F N/A 62,0 62,0 59,9 53,9 49,4 48,2 N/A
Class F N/A 62,0 62,0 62,0 56,1 50,6 49,1 44,9
A

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SIST EN 50173-1:2008/A1:2010
EN 50173-1:2007/A1:2009 - 14 -

5.2.2.5 Attenuation to crosstalk loss ratio (ACR)
Replace the title by:
5.2.2.5 Attenuation to crosstalk ratio at the near-end (ACR-N)
Replace “ACR” with “ACR-N” throughout the document.
Add the following note:
NOTE ACR-N replaces, and is equivalent to, ACR of previous editions of this standard.
5.2.2.5.1 Pair-to-pair ACR-N
Add after Equation (2):
where
i is the number of the disturbing pair,
k is the number of the disturbed pair,
… …
nd
Replace the 2 paragraph by:
The ACR-N parameter is applicable to Classes D, E, E , F and F only. The ACR-N for each pair
A A
combination of a channel shall meet the limits computed according to Equation (2), to one decimal place,
using the relevant formulae of Table 6 and Table 8. The limits shown in Table 12 are derived with
Equation (2) at key frequencies only.
Replace Table 12 by:
Table 12 – ACR-N limits for a channel at key frequencies
Minimum ACR-N
dB
Frequency 0,1 1,0 16,0 100,0 250,0 500,0 600,0 1 000,0
MHz
Class D N/A 59,3 34,5 6,1 N/A N/A N/A N/A
Class E N/A 61,0 44,9 18,2 -2,8 N/A N/A N/A
Class E N/A 61,0 45,0 19,0 -0,8 -21,4 N/A N/A
A
Class F N/A 61,0 56,9 42,1 23,1 3,1 -3,4 N/A
Class F N/A 61,0 57,0 44,7 23,1 6,9 0,7 -19,6
A
5.2.2.5.2 Power sum ACR (PSACR)
Replace the title by:
5.2.2.5.2 Power sum ACR-N (PSACR-N)

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SIST EN 50173-1:2008/A1:2010
- 15 - EN 50173-1:2007/A1:2009

Add after Equation (3):
where
k is the number of disturbed pair
… .
nd
Replace the 2 paragraph by:
The PSACR-N parameter is applicable to Classes D, E, E , F and F . The PSACR-N for each pair of a
A A
channel shall meet the limits computed according to Equation (3), to one decimal place, using the relevant
formulae of Table 6 and Table 10. The limits shown in Table 13 are derived with Equation (3) at key
frequencies only.
Replace Table 13 by:
Table 13 – PSACR-N limits for a channel at key frequencies
Minimum PSACR-N
dB
Frequency 0,1 1,0 16,0 100,0 250,0 500,0 600,0 1 000,0
MHz
Class D N/A 56,3 31,5 3,1 N/A N/A N/A N/A
Class E N/A 58,0 42,3 15,4 -5,8 N/A N/A N/A
Class E N/A 58,0 42,4 16,2 -3,7 -24,5 N/A N/A
A
Class F N/A 58,0 53,9 39,1 20.1 0,1 -6,4 N/A
Class F N/A 58,0 54,0 41,7 23,7 3,9 -2,3 -22,6
A
5.2.2.6 Equal level far end crosstalk loss (ELFEXT)
Replace the whole subclause as follows and replace “ELFEXT” by “ACR-F” throughout the document.
5.2.2.6 Attenuation to crosstalk ratio at the far-end (ACR-F)
NOTE ACR-F replaces, and differs from, ELFEXT of previous editions of this standard.
5.2.2.6.1 Pair-to-pair ACR-F
The ACR-F parameter is applicable to Classes D, E, E , F and F only.
A A
ACR-F of pairs i and k, α (i,k), is computed as follows:
i,k ACR-F
αα(,ik) = (ik, ) –α(k) [dB] (4)
ACR-F FEXT
where
i is the number of the disturbing pair;
k is the number of the disturbed pair;
α (i,k) is the far-end crosstalk loss coupled from disturbing pair i into disturbed pair k. When required, it
FEXT
shall be measured according to EN 50346.
α(k) is the insertion loss of pair k. When required, it shall be measured according to EN 50346.

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SIST EN 50173-1:200
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