Difference between revisions of "Examples of Communication Systems/General Description of DSL"

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{{Header
 
{{Header
 
|Untermenü=DSL – Digital Subscriber Line
 
|Untermenü=DSL – Digital Subscriber Line
|Vorherige Seite=Weiterentwicklungen von ISDN
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|Vorherige Seite=Further Developments of ISDN
|Nächste Seite=xDSL–Systeme
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|Nächste Seite=xDSL_Systems
 
}}
 
}}
  
==Motivation für xDSL==
+
== # OVERVIEW OF THE SECOND MAIN CHAPTER # ==
 +
<br>
  
Die verschiedenen Varianten von '''xDSL – Digital Subscriber Line''', das „x” ist ein Platzhalter für einen weiteren Buchstaben – entstanden aus dem Bedarf, dem Endkunden einen kostengünstigen hochratigen digitalen Datenzugang bereitzustellen. Bei der Konzipierung war zu beachten:
+
$\rm D$igital $\rm S$ubscriber $\rm L$ine&nbsp; &ndash; in short&nbsp; $\rm DSL$ &ndash;&nbsp; literally means only&nbsp; "digital subscriber line".&nbsp; At the same time,&nbsp; "DSL"&nbsp; was a synonym for&nbsp; "high-speed Internet access in the local loop to the end customer",&nbsp; although "high-speed"&nbsp; must be put into perspective today&nbsp; $(2018)$.
*Die sog. ''Last Mile''” – der letzte Abschnitt der Leitung, die zum Teilnehmerhaushalt führt und als '''Teilnehmeranschlussleitung''' (TAL) bezeichnet wird – stellt den größten Kostenfaktor in einem Kommunikationsnetz dar, da sich im TAL–Bereich das Netz maximal verzweigt.
+
*Überlegungen, im Teilnehmeranschlussnetz die geschätzten 130 Millionen Kilometer an Kupfer–Doppeladern durch '''Glasfaserleitungen''' zu ersetzen (''Fiber–to–the–Home'', FttH), scheiterten bis heute an den enormen Kosten der meist unterirdischen Verlegungsarbeiten.
+
xDSL has been significantly standardized by the standards committees&nbsp; [https://en.wikipedia.org/wiki/American_National_Standards_Institute $\rm ANSI$]&nbsp; $($USA$)$&nbsp; and&nbsp; [https://en.wikipedia.org/wiki/ETSI $\rm ETSI$]&nbsp; $($Europe$)$&nbsp; as well as the&nbsp; [https://en.wikipedia.org/wiki/International_Telecommunication_Union $\rm ITU$]&nbsp; $($worldwide$)$.&nbsp; Due to different pre-existing technical conditions and preferences of developers and operators,&nbsp; a large variety of nationally different versions of nominally identical xDSL standards resulted.&nbsp; In the following,&nbsp; we will restrict ourselves primarily to the German xDSL versions.
*Eine praktikable Lösung war, durch die Nutzung des bestehenden Telefonleitungsnetzes und durch geschickte Kombination verschiedener Nachrichtenübermittlungstechniken und Codierverfahren einen Breitbandanschluss anzubieten mit etwas niedrigeren Datenraten als in einem Glasfasernetz.
+
 
*Der Telefondienst – entweder analog oder digital (ISDN) – sollte gleichzeitig im gleichen Netz betrieben werden können.
+
This chapter contains in detail:
 +
 
 +
#An&nbsp; &raquo;overview of the historical development and standardization&laquo;&nbsp; of xDSL,
 +
#the&nbsp; &raquo;differences between ADSL and VDSL&laquo;&nbsp; as well as statistics on their penetration,
 +
#a brief description of xDSL from a&nbsp; &raquo;communications protocol perspective&laquo;,
 +
#the bandwidth allocations for the two&nbsp; &raquo;xDSL variants ADSL and VDSL&laquo;,&nbsp;
 +
#a detailed description of the&nbsp; &raquo;DSL transmission methods QAM, CAP and DMT&laquo;,
 +
#the problems of&nbsp; &raquo;digital signal transmission over copper twisted pairs&laquo;&nbsp; in general,
 +
#the relationship between&nbsp; &raquo;SNR,&nbsp; range and transmission rate&laquo;,
 +
#the&nbsp; &raquo;error correction measures&laquo;&nbsp; used to reduce the bit error rate.
 +
 
 +
 
 +
==Network infrastructure for DSL== 
 +
<br>
 +
 
 +
We start as in the&nbsp;  [[Examples_of_Communication_Systems/General_Description_of_ISDN#Network_infrastructure_for_ISDN|"ISDN chapter"]]&nbsp; with the  network infrastructure.&nbsp; DSL was intended to use the existing analog telephone network for cost reasons.&nbsp;
 +
 
 +
The greatest cost factor of the entire infrastructure is the&nbsp; &raquo;'''subscriber line area'''&laquo;&nbsp; between a main distribution frame&nbsp; $($e.g. "switching office"$)$&nbsp; and the subscribers.
 +
[[File:EN_LZI_T_4_3_S2_neu.png| right|frame|Structure of the local loop area]]
 +
 
 +
*In Germany,&nbsp; this so-called&nbsp; &raquo;'''last mile'''&laquo;&nbsp; is shorter than&nbsp; $4$&nbsp; kilometers on average,&nbsp; and in urban areas&nbsp; $90\%$&nbsp; of the time it is even shorter than&nbsp; $2.8$&nbsp; kilometers.
 +
 
 +
*Due to the topological conditions,&nbsp; the telephone network is increasingly branching out in a star configuration toward the end customer.  
 +
 
 +
*In order to avoid having to lay a separate copper cable to the local exchange for each subscriber,&nbsp; splitters have been installed in between and the lines bundled in correspondingly large cables.
 +
 
 +
 
 +
The&nbsp; &raquo;'''local loop area'''&raquo;&nbsp; is therefore usually made up as follows:
 +
 
 +
# &nbsp; The&nbsp; "main cable"&nbsp; with up to&nbsp; $2000$&nbsp; pairs between the local exchange&nbsp; (or the switching office)&nbsp; frame and a cable branch,
 +
# &nbsp;the&nbsp; "branch cable"&nbsp; between the cable branch and the final branch,  with up to&nbsp; $300$&nbsp; pairs and a maximum length of 500 meters,&nbsp; which is significantly shorter than a main cable,
 +
# &nbsp;the&nbsp; "house connection cable"&nbsp; between the terminal box and the network termination box at the subscriber with two pairs of wires.
 +
 
 +
 +
 
 +
==xDSL types and terms== 
 +
<br>
 +
 
 +
{{BlaueBox|TEXT=
 +
$\text{Motivation for Digital Subscriber Line}$&nbsp;
 +
 
 +
$\rm DSL$&nbsp; $($"Digital Subscriber Line"$)$&nbsp; arose from the need,&nbsp; '''to provide low cost high rate digital data access to the end user'''.&nbsp; <br>During the design process,&nbsp; it was necessary to take into account:
 +
*As explained in the last section,&nbsp; the&nbsp; "last mile"&nbsp; is the largest cost factor in a communications network.
 +
 
 +
*Considerations to replace the estimated&nbsp; 130&nbsp; million kilometers of copper twisted pairs in the local loop network with fiber optic lines&nbsp; $($fiber-to-the-home,&nbsp; $\rm FttH)$&nbsp; have failed to date due to the enormous costs of the mostly underground laying work.
 +
 
 +
*A viable solution was to offer a broadband connection with somewhat lower data rates than in a fiber optic network by using the existing telephone line network and by cleverly combining different transmission techniques and coding methods.
 +
 
 +
*The telephone service &ndash; either analog or digital&nbsp; $\rm (ISDN)$&nbsp; &ndash; should be able to operate simultaneously on the same network.}}
 +
 
 +
 
 +
Before we turn to the historical DSL development up to the current state,&nbsp; the various types of&nbsp; "$\rm xDSL$"&nbsp; must first be defined and some terms explained.&nbsp; <u>Note:</u>
 +
#Here,&nbsp;"$\rm x$"&nbsp; is merely a placeholder that designates the various DSL standards.
 +
#The technical features will be covered in depth in the next chapters.
 +
 
 +
 
 +
'''Part of the xDSL standard:'''
 +
*$\text{ADSL}$&nbsp; &nbsp; "Asymmetric Digital Subscriber Line: <br>Asymmetric data transmission technology with data rates of&nbsp; $8$&nbsp; Mbit/s to the subscriber&nbsp; $($"downstream"$)$&nbsp; and&nbsp; $1$&nbsp; Mbit/s in the opposite direction&nbsp; $($"upstream"$)$.
  
Die Grafik zeigt den Teilnehmeranschlussbereich (TAL) zwischen Ortsvermittlungsstelle (OVSt) und Endkunden (EVZ).
+
*$\text{ADSL2}$&nbsp; and&nbsp; $\text{ADSL2+}$: <br>Extensions of ADSL with data rates of up to&nbsp; $25$&nbsp; Mbit/s&nbsp; $($"downstream"$)$&nbsp; and up to&nbsp; $1$&nbsp; Mbit/s&nbsp; $($"upstream"$)$. <br>The data rate is dynamically negotiated depending on the channel state.
 +
 
 +
*$\text{Re &ndash; ADSL2}$: <br>Another extension of ADSL with about&nbsp; $30\%$&nbsp;  range gain at a data rate of&nbsp;  $768$&nbsp; kbit/s downstream.
 +
 
 +
*$\text{HDSL}$&nbsp; –&nbsp; "High Data Rate Digital Subscriber Line": <br>Symmetrical data transmission technology&nbsp; &ndash;&nbsp; i.e. equal rates in downstream and upstream&nbsp; &ndash;&nbsp; with data rates between&nbsp; $1.54$&nbsp; Mbit/s and&nbsp; $2.04$&nbsp; Mbit/s. <br><u>Note:</u>&nbsp; The name&nbsp; "HDSL"&nbsp; suggests higher data rates than ADSL;&nbsp; however,&nbsp; this is not the case.
 +
 
 +
*$\text{SDSL}$&nbsp; –&nbsp; "Symmetric Digital Subscriber Line": <br>Symmetrical data transmission at rates of up to&nbsp; $3$&nbsp; Mbit/s.&nbsp; With four-wire wiring&nbsp; $($two copper twisted pairs$)$,&nbsp; a maximum of&nbsp; $4$&nbsp; Mbit/s can be transmitted.&nbsp; Alternatively,&nbsp; the range can be increased at the expense of bandwidth.
 +
 
 +
*$\text{VDSL}$&nbsp; –&nbsp; "Very High Data Rate Digital Subscriber Line": <br>A newer transmission technology based on QAM that operates in the asymmetrical variant with bit rates of&nbsp; $25$&nbsp; to&nbsp; $50$&nbsp; Mbit/s&nbsp; downstream and&nbsp; $5$ to&nbsp; $10$&nbsp; Mbit/s upstream.&nbsp; The symmetrical variant has the same data transmission rates in upstream and downstream.
 +
 
 +
*$\text{VDSL2}$&nbsp; –&nbsp; "Very High Data Rate Digital Subscriber Line 2": <br>Transmission technology with the currently (2009) highest total data rate of up to&nbsp; $200$&nbsp; Mbit/s.&nbsp; The process is based on DMT&nbsp; $($"Discrete Multitone Transmission"$)$.
 +
 
 +
*$\text{UDSL}$ &nbsp; or &nbsp; $\text{UADSL}$&nbsp; &nbsp; –&nbsp; "Universal (Asymmetric) Digital Subscriber Line".
 +
 
 +
 
 +
'''Not part of the xDSL standard:'''
 +
#There are also many products circulating under&nbsp; "DSL"&nbsp; that are not part of the xDSL standard.
 +
#They are often only intended to make it clear that fast data access is involved.&nbsp;
 +
 
 +
 
 +
These include:
 +
*$\text{cableDSL}$: &nbsp; Brand name of the German company TELES AG, which offers high-speed Internet access via cable. The name was chosen for marketing reasons only.
 +
 
 +
*$\text{skyDSL}$:&nbsp; Brand name for Internet access available throughout Europe via satellite with up to&nbsp; $24$&nbsp; Mbit/s downstream. <br>The upstream here is via POTS&nbsp; $($"Plain old telephone service"$)$&nbsp; or&nbsp; [[Examples_of_Communication_Systems/General_Description_of_ISDN|ISDN ]]&nbsp; $($"Integrated Services Digital Network"$)$.
 +
 
 +
*$\text{T-DSL via satellite}$: &nbsp; Brand name for a downstream Internet access of Telekom via satellite;&nbsp; uses a conventional modem or an ISDN connection for transmission.
 +
 
 +
*$\text{WDSL}$&nbsp; –&nbsp; "Wireless Digital Subscriber Line":&nbsp; Brand name of a German company that uses wireless technology to enable data rates of up to&nbsp; $108$&nbsp; Mbit/s in DSL-free areas.
 +
 
 +
*$\text{mvoxSatellit}$: &nbsp; Brand name of an Internet access with&nbsp; "WiMAX-like radio technology",&nbsp; which like WDSL and PortableDSL is only an auxiliary construct for DSL-free areas.
  
 
   
 
   
==xDSL-Arten und -Begriffe==
+
==Historical development of xDSL standardizations ==
 +
<br>
 +
 
 +
The need for digital subscriber lines to improve line utilization and increase customer convenience was recognized as early as the 1970s.&nbsp; After the ISDN specification in the early 1980s,&nbsp; the actual development of DSL began.
 +
 
 +
*This development was influenced by the findings of many groups located around the world.&nbsp; Accordingly,&nbsp; the standardization proceeded in an unstructured manner.
 +
 
 +
*From the list on the right,&nbsp; it is clear that different committees around the world were in charge of the various standards.
 +
 
 +
*In the industry,&nbsp; the technical realizations of the individual xDSL standards often deviated noticeably from the specification.&nbsp;
 +
 
 +
*Some standards were started as projects even before the specification,&nbsp; since the industry parties were also represented in the standardization committees.
  
Bevor wir uns der historischen Entwicklung von DSL bis zum heutigen Stand zuwenden, müssen zuerst die verschiedenen xDSL–Arten definiert und einige Begriffe erklärt werden. Die technischen Merkmale werden in den nächsten Kapiteln in der Tiefe behandelt.
 
*'''ADSL''' – ''Asymmetric Digital Subscriber Line'': Asymmetrische Datenübertragungstechnik mit Datenübertragungsraten von 8 Mbit/s zum Teilnehmer (''Downstream'') und 1 Mbit/s in der Gegenrichtung (''Upstream'').
 
*'''ADSL2''' und '''ADSL2+''': Erweiterungen von ADSL mit Datenraten bis 25 Mbit/s zum Teilnehmer und bis 1 Mbit/s im Upstream. Die Datenrate wird je nach Kanalzustand dynamisch ausgehandelt.
 
*'''Re–ADSL2''': Eine weitere Erweiterung von ADSL mit etwa 30% Reichweitengewinn bei einer Datenrate von 768 kbit/s im Downstream.
 
*'''HDSL''' – ''High Data Rate Digital Subscriber Line'': Symmetrische Datenübertragungstechnik – also gleiche Raten in Down– und Upstream – mit Datenraten zwischen 1.54 Mbit/s und 2.04 Mbit/s. ''Anmerkung'': Der Name „HDSL” suggeriert höhere Datenraten als ADSL.
 
*'''SDSL''' – ''Symmetric Digital Subscriber Line'': Symmetrische Datenübertragung mit Raten bis zu 3 Mbit/s. Bei vieradriger Beschaltung (zwei Kupfer-Doppeladern) können maximal 4 Mbit/s übertragen werden. Alternativ kann man auch die Reichweite auf Kosten der Bandbreite erhöhen.
 
*'''VDSL''' – ''Very High Data Rate Digital Subscriber Line'': Eine neuere, auf QAM basierende Übertragungstechnik, die in der asymmetrischen Variante mit Bitraten von 25 bis 50 Mbit/s im Downstream und von 5 bis 10 Mbit/s im Upstream arbeitet. Die symmetrische Variante weist im Upstream und Downstream jeweils gleiche Datenübertragungsraten auf.
 
*'''VDSL2''' – ''Very High Data Rate Digital Subscriber Line 2'': Übertragungstechnologie mit der derzeit (2009) größten Gesamtdatenrate von bis zu 200 Mbit/s. Das Verfahren basiert auf DMT (''Discrete Multitone Transmission'').
 
*'''UDSL''' bzw. '''UADSL''' – ''Universal (Asymmetric) Digital Subscriber Line''.
 
Unter „DSL” kursieren daneben auch viele Produkte, die nicht dem xDSL–Standard zuzuordnen sind. Oft sollen sie nur deutlich machen, dass es sich um einen schnellen Datenzugang handelt. Dazu gehören:
 
*'''cableDSL''': Markenname des deutschen Unternehmens TELES AG, das einen schnellen Internetzugang über Kabel anbietet. Der Name wurde nur aus Marketinggründen gewählt.
 
*'''skyDSL''': Markenname für einen europaweit verfügbaren Internetzugang über Satelliten mit bis zu 24 Mbit/s im Downstream. Der Upstream erfolgt hier über POTS oder ISDN.
 
*'''T-DSL via Satellit''': Markenname für einen Downstream–Internetzugang der Telekom über Satellit; verwendet zum Senden ein herkömmliches Modem oder eine ISDN–Verbindung.
 
*'''WDSL''' – ''Wireless Digital Subscriber Line'': Markenname eines deutschen Unternehmens, das mit Funktechnik in DSL–freien Gebieten Datenraten bis zu 108 Mbit/s ermöglicht.
 
*'''mvoxDSL''': Markenname eines Internetzugangs mit „WiMAX–ähnlicher Funktechnik”, der ebenso wie WDSL und PortableDSL nur ein Hilfskonstrukt für DSL–freie Gebiete darstellt.
 
  
 +
The graph illustrates the relationships between milestones in the theoretical and practical design of transmission systems.
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 +
 +
 +
[[File:EN_Bei_2_1_s3_v4.png|right|frame|Milestones of the industrial xDSL development]]
 +
$\text{Milestones of DSL development in short form:}$
 +
 +
'''1986'''  &nbsp; A first concept for&nbsp; $\rm HDSL$&nbsp; $($"'''H'''igh-bit-rate '''D'''igital '''S'''ubscriber '''L'''ine"$)$&nbsp; is defined by AT&T,&nbsp; Bell Laboratories and Bellcore.
 +
 +
'''1989'''  &nbsp; First HDSL prototypes appear;  &nbsp; &nbsp;  &rArr; &nbsp; &nbsp; Bellcore meanwhile works on the conceptual definition of&nbsp; $\rm  ADSL$ &nbsp; $($"'''A'''symmetric '''D'''igital '''S'''ubscriber '''L'''ine"$)$.
 +
 +
'''1992'''  &nbsp; First publication of the&nbsp; $\text{ANSI Technical Report E1T1/92-002R1}$:<br>"High-bit-rate Digital Subscriber Line";&nbsp; &nbsp;  &rArr; &nbsp; &nbsp; The first ADSL prototypes  appear.
 +
 +
'''1994'''  &nbsp; The&nbsp; $\rm VDSL$&nbsp; concept&nbsp; $($"'''V'''ery-high-speed '''D'''igital '''S'''ubscriber '''L'''ine"$)$&nbsp; is discussed for the first time.
 +
 +
'''1995'''  &nbsp; Publication of the&nbsp; $\text{ETSI Technical Report ETR 152:}$&nbsp; "High-bit-rate Digital Subscriber Line"&nbsp; and&nbsp; "Transmission Systems on Metallic Local Lines";  <br>&rArr; &nbsp; &nbsp;  Publication of&nbsp; $\text{ADSL Standard ANSI T1.413}$:&nbsp; $($"Asymmetric Digital Subscriber Line Metallic Interface"$)$; &nbsp; &nbsp;  &rArr; &nbsp; &nbsp; First field trials with ADSL in the USA .
 +
 +
'''1996'''  &nbsp; First publication of the&nbsp; $\text{ETSI Technical Report ETR 328}$:&nbsp; "Asymmetric Digital Subscriber Line"&nbsp; and&nbsp; "Transmission and Multiplexing".
 +
 +
'''04/1998'''  First publication of&nbsp; $\text{ETSI Technical Specification TS 101 270}$:&nbsp; "Very-high-speed Digital Subscriber Line";  &nbsp; &nbsp;  &rArr; &nbsp; &nbsp;  Almost simultaneously, first publication of&nbsp; $\text{ANSI Draft Technical Document T1E1.4/98-043R1}$:&nbsp; "Very-high-speed Digital Subscriber Lines". 
 +
 +
'''10/1998''' First publication of&nbsp; $\text{ITU Recommendation G.991.1}$:&nbsp; "High-bit-rate Digital Subscriber Line Transceivers";  &nbsp; &nbsp;  &rArr; &nbsp; &nbsp; Almost simultaneously publication of&nbsp; $\text{ETSI Technical Specification TS 101 135}$:&nbsp;  "High-bit-rate Digital Subscriber Line &ndash; Transmission Systems on Metallic Local Lines". 
 +
 +
'''11/1998''' Publication of&nbsp; $\text{ETSI Technical Specification TS 101 388 V1.1.1}$:&nbsp; "Asymmetric Digital Subscriber Line &ndash; European Specific Requirements".
 +
 +
'''1999'''  &nbsp; In June,&nbsp; publication of&nbsp; $\text{ITU Recommendations G.992.1}$:&nbsp; "Asymmetric Digital Subscriber Line &ndash; Transceivers"&nbsp; and&nbsp; $\text{G.992.2}$:&nbsp; "Splitterless Asymmetric Digital Subscriber Line &ndash; Transceivers"; &nbsp; &nbsp;  &rArr; &nbsp; &nbsp; On July 22, Deutsche Telekom AG offers ADSL in Germany for the first time&nbsp; $\text{(T-DSL 768)}$.
 +
 +
'''2001'''  &nbsp; In February,&nbsp; publication of&nbsp; $\text{ITU Recommendation G.991.2}$:&nbsp; "Single-pair High-speed Digital Subscriber Line Transceivers"; &nbsp; &nbsp;  &rArr; &nbsp; &nbsp;  In November,&nbsp; publication of&nbsp; $\text{ITU Recommendation G.993.1}$:&nbsp; "Very-high-speed Digital Subscriber Line transceivers".
 +
 +
'''2002'''  &nbsp; First publications of&nbsp; $\text{ITU Recommendations G.992.3}$:&nbsp; "Asymmetric Digital Subscriber Line Transceivers 2"&nbsp; $\rm (ADSL2)$&nbsp; and&nbsp; $\text{G.992.4}$:&nbsp; "Splitterless ADSL2".
 +
 +
'''2003'''  &nbsp; First publication of&nbsp; $\text{ITU Recommendation G.992.5}$:&nbsp; "Asymmetric Digital Subscriber Line"&nbsp; $\rm (ADSL)$&nbsp; Transceivers"&nbsp; and &nbsp; "Extended-bandwidth ADSL2"&nbsp; $\rm (ADSL2+)$.
 +
 +
'''02/2006'''  &nbsp; Publication of&nbsp; $\text{ITU Recommendation G.993.2}$: "Very-high-speed Digital Subscriber Line Transceivers 2"&nbsp; $\rm  (VDSL2)$. 
 +
 +
'''10/2006'''  &nbsp;Deutsche Telekom AG offers VDSL2 to end customers in selected cities for the first time.
 
   
 
   
==Historische Entwicklung von xDSL – Standardisierungen ==
 
  
Schon in den 1970er Jahren wurde die Notwendigkeit digitaler Teilnehmeranschlüsse zur Verbesserung der Leitungsausnutzung und zur Erhöhung des Kundenkomforts erkannt. Nach der ISDN–Spezifikation Anfang der 1980er Jahre begann dann die eigentliche Entwicklung von DSL.
+
== Development of ADSL and VDSL in Europe ==
*Diese Entwicklung wurde von den Erkenntnissen vieler weltweit angesiedelter Gruppen beeinflusst. Dementsprechend unstrukturiert verlief die Standardisierung. Aus der Liste auf der nächsten Seite wird deutlich, dass bei den verschiedenen Standards weltweit unterschiedliche Gremien federführend waren.
+
<br>
*In der Industrie wichen die technischen Realisierungen der einzelnen xDSL–Standards von der Spezifikation oft merklich ab. So wurden manche Standards teilweise schon vor der Spezifikation als Projekte begonnen, da die Industrieparteien auch in den Gremien zur Standardisierung vertreten waren.
+
From the above compilation it can be seen that the&nbsp; &raquo;'''ADSL standardization'''&laquo;&nbsp; was predominantly driven by&nbsp; [https://en.wikipedia.org/wiki/American_National_Standards_Institute $\rm ANSI$]&nbsp; $($"American National Standards Institute"$)$&nbsp; and that&nbsp; [https://en.wikipedia.org/wiki/ETSI $\rm ETSI$]&nbsp; $($"European Telecommunications Standards Institute"$)$&nbsp; followed shortly thereafter in each case:
 +
#The first ADSL standard &nbsp; "$\text{ANSI T1.413}$" &nbsp; from 1995 was predominantly optimized for video-on-demand services,&nbsp; which is also made clear by the ratio of the downstream and upstream data rates defined herein:&nbsp; $1.5$&nbsp; Mbit/s and&nbsp; $16$&nbsp; kbit/s,&nbsp; $3$&nbsp; Mbit/s and&nbsp; $16$&nbsp; kbit/s, and finally&nbsp; $6$&nbsp; Mbit/s and&nbsp; $64$&nbsp;kbit/s.
 +
#The frequency range was originally defined in such a way that ADSL could only be used to operate an analog telephone on the access line.&nbsp; ETSI published a technical report &nbsp; "$\text{ETR 328}$" &nbsp; in 1996 with only a few detailed changes and the possibility to transmit&nbsp; $2048$&nbsp; kbit/s.
 +
#Since the second version of the ANSI standard also allowed only one additional analog telephone,&nbsp; ETSI then defined an ADSL system that differed both in bit rates and in the possibility of using an ISDN basic access on the same twisted pair.
 +
#The ANSI and ETSI standardization efforts of the previous years resulted in the&nbsp; [https://en.wikipedia.org/wiki/International_Telecommunication_Union "ITU"] recommendation&nbsp; "$\text{G.992.1}$" &nbsp; in 1999,&nbsp; which includes both standards and thus allows many options for the implementation.
 +
 
 +
 
 +
However,&nbsp; the many options led to major conceptual differences at the end of the 1990s&nbsp; &ndash;&nbsp; worldwide,&nbsp; within Europe and also nationally&nbsp; &ndash;&nbsp; depending on the semiconductor manufacturer,&nbsp; among other things.&nbsp; Only a few systems,&nbsp; modems,&nbsp; and measuring devices interoperated with other manufacturers.
 +
 
 +
To counteract this proliferation,&nbsp; The&nbsp; "Deutsche Telekom AG"&nbsp; passed the technical guideline&nbsp; "$\text{1TR112}$" &nbsp; at the end of 2001,&nbsp; defining all the necessary interface parameters to ensure the interoperability of different manufacturer modems on the provider and customer side.&nbsp;
 +
*Due to Telekom's market power,&nbsp; this became the quasi-standard for Germany.
 +
 
 +
*Furthermore,&nbsp; only those ADSL variants were used in Germany that allowed simultaneous operation of ISDN at any time.&nbsp; Thus,&nbsp; when switching from POTS to ISDN,&nbsp; it was not necessary to change the ADSL version as well.
 +
 
  
Die Grafik veranschaulicht Zusammenhänge zwischen
+
The&nbsp; &raquo;'''VDSL standardization'''&laquo;&nbsp; relevant for Europe was decisively shaped by ETSI and often happened in parallel to the American activities.&nbsp; Overall,&nbsp; VDSL standardization proceeded in a more orderly fashion than ADSL.&nbsp; The 3-step plan adopted by ETSI provided for:
*Meilensteinen beim theoretischen und praktischen Entwurf von Übertragungssystemen,
+
*Stage 1:&nbsp; Functional and electrical requirements for VDSL systems,
*parallel verlaufenden Fortschritten in der Halbleiterentwicklung, und der
+
 
*Realisierung der einzelnen xDSL–Standards mit den entsprechenden Datenraten.
+
*Stage 2:&nbsp; Transmission coding and access method requirements,
 +
 
 +
*Stage 3:&nbsp; Interoperability requirements.
 +
 
 +
 
 +
These efforts culminated in April 1998 in the publication of the ETSI Technical Specification&nbsp; "$\text{TS 101 270-1}$",&nbsp; which defines as modulation methods both&nbsp; [[Modulation_Methods/Further_OFDM_Applications#A_brief_description_of_DSL_-_Digital_Subscriber_Line|$\rm DMT$]]&nbsp; $($"Discrete Multitone Transmission"$)$&nbsp;  and&nbsp; [[Modulation_Methods/Quadrature_Amplitude_Modulation|$\rm QAM$]]&nbsp; $($"Quadrature Amplitude Modulation"$)$.&nbsp; The semiconductor manufacturers could not agree on a worldwide line code standard for a long time and there was even talk of the&nbsp; "VDSL Line Code War".
 +
 
 +
In 2003,&nbsp; at the so-called&nbsp; "VDSL Olympics",&nbsp; the decision was made in favor of DMT and against QAM or the slightly modified variant&nbsp; [[Examples_of_Communication_Systems/xDSL_as_Transmission_Technology#Carrierless_Amplitude_Phase_Modulation|$\rm CAP$]]&nbsp; $($"Carrierless Amplitude Phase Modulation"$)$,&nbsp; namely
 +
*because of the robustness of DMT against narrowband interference sources,
 +
 
 +
*although QAM/ CAP would allow a faster call setup.
  
  
Hier die Meilensteine der DSL–Entwicklung in Kurzform:
 
:'''1986'''  Ein erstes Konzept für HDSL ('''''H'''igh–bit–rate '''D'''igital '''S'''ubscriber '''L'''ine'') wird von AT&T, Bell Laboratories und Bellcore definiert.
 
:'''1989'''  Erste HDSL–Prototypen erscheinen.  #  Bellcore arbeitet inzwischen an der konzeptionellen Definition von ADSL.
 
:'''1992'''  Im Februar erstmalige Veröffentlichung des '''ANSI Technical Report E1T1/92–002R1''': „''High Bit–rate Digital Subscriber Line'' – HDSL”.  #  Die ersten Prototypen für ADSL ('''''A'''symmetric '''D'''igital '''S'''ubscriber '''L'''ine'') erscheinen.
 
:'''1994'''  Das VDSL–Konzept ('''''V'''ery–high–speed '''D'''igital '''S'''ubscriber '''L'''ine'') wird erstmalig diskutiert.
 
:'''1995'''  Veröffentlichung des '''ETSI Technical Report ETR 152''': „''High–bit–rate Digital Subscriber Line'' (HDSL)” sowie „''Transmission Systems on Metallic Local Lines''”.  #  Erste Feldversuche mit ADSL in den USA.  #  Veröffentlichung des '''ADSL–Standards ANSI T1.413''': „''Asymmetric Digital Subscriber Line'' (ADSL) ''Metallic Interface''”.
 
:'''1996'''  Erstmalige Veröffentlichung des '''ETSI Technical Report ETR 328''': „Asymmetric Digital Subscriber Line (ADSL)” sowie „Transmission and Multiplexing (TM)”.
 
:'''1998'''  Im April erstmalige Veröffentlichung der '''ETSI Technical Specification TS 101 270–1 V1.1.1''': „''Very–high–speed Digital Subscriber Line'' (VDSL)”.  #  Nahezu zeitgleich erstmalige Veröffentlichung des '''ANSI Draft Technical Document T1E1.4/98–043R1''': „''Very–high–speed Digital Subscriber Lines''”.  #  Im Oktober erste Veröffentlichung der '''ITU–Empfehlung G.991.1''': „''High–bit–rate Digital Subscriber Line'' (HDSL) ''Transceivers''”.  #  Nahezu zeitgleich Veröffentlichung der '''ETSI Technical Specification TS 101 135''': „''High–bit–rate Digital Subscriber Line'' (HDSL) – ''Transmission Systems on Metallic Local Lines''”.  #  Im November Veröffentlichung der '''ETSI Technical Specification TS 101 388 V1.1.1''': „''Asymmetric Digital Subscriber Line'' (ADSL) – ''European Specific Requirements''”.
 
:'''1999'''  Im Juni Veröffentlichung der '''ITU–Empfehlungen G.992.1''': „''Asymmetric Digital Subscriber Line'' (ADSL) ''Transceivers''” und '''G.992.2''': „''Splitterless Asymmetric Digital Subscriber Line'' (ADSL) ''Transceivers''”.  #  Am 22.07. bietet die Deutsche Telekom AG erstmals ADSL in Deutschland an (T–DSL 768).
 
:'''2001'''  Im Februar Veröffentlichung der '''ITU–Empfehlung G.991.2''': „''Single–pair High–speed Digital Subscriber Line'' (SHDSL) ''Transceivers''”.  #  Im November Veröffentlichung der '''ITU–Empfehlung G.993.1''': ''Very–high–speed Digital Subscriber Line transceivers'' (VDSL).
 
:'''2002'''  Erstmalige Veröffentlichungen der '''ITU–Empfehlungen G.992.3''': „''Asymmetric Digital Subscriber Line Transceivers 2'' (ADSL2)” sowie '''G.992.4''': „''Splitterless Asymmetric Digital Subscriber Line Transceivers 2'' (splitterless ADSL2)” .
 
:'''2003'''  Erste Veröffentlichung der '''ITU–Empfehlung G.992.5''': „''Asymmetric Digital Subscriber Line'' (ADSL) ''Transceivers – Extended-bandwidth ADSL2'' (ADSL2+)” .
 
:'''2006'''  Im Februar Veröffentlichung der '''ITU–Empfehlung G.993.2''': „''Very–high–speed Digital Subscriber Line Transceivers 2'' (VDSL2)”.  #  Im Oktober bietet die Deutsche Telekom AG erstmals für Endkunden in ausgewählten Städten VDSL2 an.
 
 
 
 
  
== Europäische ADSL- und VDSL-Entwicklung ==
 
== Die rasante Entwicklung der DSL–Anschlüsse  ==
 
==DSL–Verbreitung um das Jahr 2008 ==
 
==DSL-Entwicklung und Zielvorgaben für Deutschland== 
 
==Aufgabe zu Kapitel 2.1 ==
 
  
  
 +
==Exercises for the chapter ==
 +
<br>
 +
[[Exercise_2.1:_General_Description_of_xDSL|Exercise 2.1: General Description of xDSL]]
  
  
  
 
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Latest revision as of 22:01, 21 March 2023

# OVERVIEW OF THE SECOND MAIN CHAPTER #


$\rm D$igital $\rm S$ubscriber $\rm L$ine  – in short  $\rm DSL$ –  literally means only  "digital subscriber line".  At the same time,  "DSL"  was a synonym for  "high-speed Internet access in the local loop to the end customer",  although "high-speed"  must be put into perspective today  $(2018)$.

xDSL has been significantly standardized by the standards committees  $\rm ANSI$  $($USA$)$  and  $\rm ETSI$  $($Europe$)$  as well as the  $\rm ITU$  $($worldwide$)$.  Due to different pre-existing technical conditions and preferences of developers and operators,  a large variety of nationally different versions of nominally identical xDSL standards resulted.  In the following,  we will restrict ourselves primarily to the German xDSL versions.

This chapter contains in detail:

  1. An  »overview of the historical development and standardization«  of xDSL,
  2. the  »differences between ADSL and VDSL«  as well as statistics on their penetration,
  3. a brief description of xDSL from a  »communications protocol perspective«,
  4. the bandwidth allocations for the two  »xDSL variants ADSL and VDSL«, 
  5. a detailed description of the  »DSL transmission methods QAM, CAP and DMT«,
  6. the problems of  »digital signal transmission over copper twisted pairs«  in general,
  7. the relationship between  »SNR,  range and transmission rate«,
  8. the  »error correction measures«  used to reduce the bit error rate.


Network infrastructure for DSL


We start as in the  "ISDN chapter"  with the network infrastructure.  DSL was intended to use the existing analog telephone network for cost reasons. 

The greatest cost factor of the entire infrastructure is the  »subscriber line area«  between a main distribution frame  $($e.g. "switching office"$)$  and the subscribers.

Structure of the local loop area
  • In Germany,  this so-called  »last mile«  is shorter than  $4$  kilometers on average,  and in urban areas  $90\%$  of the time it is even shorter than  $2.8$  kilometers.
  • Due to the topological conditions,  the telephone network is increasingly branching out in a star configuration toward the end customer.
  • In order to avoid having to lay a separate copper cable to the local exchange for each subscriber,  splitters have been installed in between and the lines bundled in correspondingly large cables.


The  »local loop area»  is therefore usually made up as follows:

  1.   The  "main cable"  with up to  $2000$  pairs between the local exchange  (or the switching office)  frame and a cable branch,
  2.  the  "branch cable"  between the cable branch and the final branch, with up to  $300$  pairs and a maximum length of 500 meters,  which is significantly shorter than a main cable,
  3.  the  "house connection cable"  between the terminal box and the network termination box at the subscriber with two pairs of wires.


xDSL types and terms


$\text{Motivation for Digital Subscriber Line}$ 

$\rm DSL$  $($"Digital Subscriber Line"$)$  arose from the need,  to provide low cost high rate digital data access to the end user
During the design process,  it was necessary to take into account:

  • As explained in the last section,  the  "last mile"  is the largest cost factor in a communications network.
  • Considerations to replace the estimated  130  million kilometers of copper twisted pairs in the local loop network with fiber optic lines  $($fiber-to-the-home,  $\rm FttH)$  have failed to date due to the enormous costs of the mostly underground laying work.
  • A viable solution was to offer a broadband connection with somewhat lower data rates than in a fiber optic network by using the existing telephone line network and by cleverly combining different transmission techniques and coding methods.
  • The telephone service – either analog or digital  $\rm (ISDN)$  – should be able to operate simultaneously on the same network.


Before we turn to the historical DSL development up to the current state,  the various types of  "$\rm xDSL$"  must first be defined and some terms explained.  Note:

  1. Here, "$\rm x$"  is merely a placeholder that designates the various DSL standards.
  2. The technical features will be covered in depth in the next chapters.


Part of the xDSL standard:

  • $\text{ADSL}$  –  "Asymmetric Digital Subscriber Line:
    Asymmetric data transmission technology with data rates of  $8$  Mbit/s to the subscriber  $($"downstream"$)$  and  $1$  Mbit/s in the opposite direction  $($"upstream"$)$.
  • $\text{ADSL2}$  and  $\text{ADSL2+}$:
    Extensions of ADSL with data rates of up to  $25$  Mbit/s  $($"downstream"$)$  and up to  $1$  Mbit/s  $($"upstream"$)$.
    The data rate is dynamically negotiated depending on the channel state.
  • $\text{Re – ADSL2}$:
    Another extension of ADSL with about  $30\%$  range gain at a data rate of  $768$  kbit/s downstream.
  • $\text{HDSL}$  –  "High Data Rate Digital Subscriber Line":
    Symmetrical data transmission technology  –  i.e. equal rates in downstream and upstream  –  with data rates between  $1.54$  Mbit/s and  $2.04$  Mbit/s.
    Note:  The name  "HDSL"  suggests higher data rates than ADSL;  however,  this is not the case.
  • $\text{SDSL}$  –  "Symmetric Digital Subscriber Line":
    Symmetrical data transmission at rates of up to  $3$  Mbit/s.  With four-wire wiring  $($two copper twisted pairs$)$,  a maximum of  $4$  Mbit/s can be transmitted.  Alternatively,  the range can be increased at the expense of bandwidth.
  • $\text{VDSL}$  –  "Very High Data Rate Digital Subscriber Line":
    A newer transmission technology based on QAM that operates in the asymmetrical variant with bit rates of  $25$  to  $50$  Mbit/s  downstream and  $5$ to  $10$  Mbit/s upstream.  The symmetrical variant has the same data transmission rates in upstream and downstream.
  • $\text{VDSL2}$  –  "Very High Data Rate Digital Subscriber Line 2":
    Transmission technology with the currently (2009) highest total data rate of up to  $200$  Mbit/s.  The process is based on DMT  $($"Discrete Multitone Transmission"$)$.
  • $\text{UDSL}$   or   $\text{UADSL}$    –  "Universal (Asymmetric) Digital Subscriber Line".


Not part of the xDSL standard:

  1. There are also many products circulating under  "DSL"  that are not part of the xDSL standard.
  2. They are often only intended to make it clear that fast data access is involved. 


These include:

  • $\text{cableDSL}$:   Brand name of the German company TELES AG, which offers high-speed Internet access via cable. The name was chosen for marketing reasons only.
  • $\text{skyDSL}$:  Brand name for Internet access available throughout Europe via satellite with up to  $24$  Mbit/s downstream.
    The upstream here is via POTS  $($"Plain old telephone service"$)$  or  ISDN   $($"Integrated Services Digital Network"$)$.
  • $\text{T-DSL via satellite}$:   Brand name for a downstream Internet access of Telekom via satellite;  uses a conventional modem or an ISDN connection for transmission.
  • $\text{WDSL}$  –  "Wireless Digital Subscriber Line":  Brand name of a German company that uses wireless technology to enable data rates of up to  $108$  Mbit/s in DSL-free areas.
  • $\text{mvoxSatellit}$:   Brand name of an Internet access with  "WiMAX-like radio technology",  which like WDSL and PortableDSL is only an auxiliary construct for DSL-free areas.


Historical development of xDSL standardizations


The need for digital subscriber lines to improve line utilization and increase customer convenience was recognized as early as the 1970s.  After the ISDN specification in the early 1980s,  the actual development of DSL began.

  • This development was influenced by the findings of many groups located around the world.  Accordingly,  the standardization proceeded in an unstructured manner.
  • From the list on the right,  it is clear that different committees around the world were in charge of the various standards.
  • In the industry,  the technical realizations of the individual xDSL standards often deviated noticeably from the specification. 
  • Some standards were started as projects even before the specification,  since the industry parties were also represented in the standardization committees.


The graph illustrates the relationships between milestones in the theoretical and practical design of transmission systems.


Milestones of the industrial xDSL development

$\text{Milestones of DSL development in short form:}$

1986   A first concept for  $\rm HDSL$  $($"High-bit-rate Digital Subscriber Line"$)$  is defined by AT&T,  Bell Laboratories and Bellcore.

1989   First HDSL prototypes appear;     ⇒     Bellcore meanwhile works on the conceptual definition of  $\rm ADSL$   $($"Asymmetric Digital Subscriber Line"$)$.

1992   First publication of the  $\text{ANSI Technical Report E1T1/92-002R1}$:
"High-bit-rate Digital Subscriber Line";    ⇒     The first ADSL prototypes appear.

1994   The  $\rm VDSL$  concept  $($"Very-high-speed Digital Subscriber Line"$)$  is discussed for the first time.

1995   Publication of the  $\text{ETSI Technical Report ETR 152:}$  "High-bit-rate Digital Subscriber Line"  and  "Transmission Systems on Metallic Local Lines";
⇒     Publication of  $\text{ADSL Standard ANSI T1.413}$:  $($"Asymmetric Digital Subscriber Line Metallic Interface"$)$;     ⇒     First field trials with ADSL in the USA .

1996   First publication of the  $\text{ETSI Technical Report ETR 328}$:  "Asymmetric Digital Subscriber Line"  and  "Transmission and Multiplexing".

04/1998 First publication of  $\text{ETSI Technical Specification TS 101 270}$:  "Very-high-speed Digital Subscriber Line";     ⇒     Almost simultaneously, first publication of  $\text{ANSI Draft Technical Document T1E1.4/98-043R1}$:  "Very-high-speed Digital Subscriber Lines".

10/1998 First publication of  $\text{ITU Recommendation G.991.1}$:  "High-bit-rate Digital Subscriber Line Transceivers";     ⇒     Almost simultaneously publication of  $\text{ETSI Technical Specification TS 101 135}$:  "High-bit-rate Digital Subscriber Line – Transmission Systems on Metallic Local Lines".

11/1998 Publication of  $\text{ETSI Technical Specification TS 101 388 V1.1.1}$:  "Asymmetric Digital Subscriber Line – European Specific Requirements".

1999   In June,  publication of  $\text{ITU Recommendations G.992.1}$:  "Asymmetric Digital Subscriber Line – Transceivers"  and  $\text{G.992.2}$:  "Splitterless Asymmetric Digital Subscriber Line – Transceivers";     ⇒     On July 22, Deutsche Telekom AG offers ADSL in Germany for the first time  $\text{(T-DSL 768)}$.

2001   In February,  publication of  $\text{ITU Recommendation G.991.2}$:  "Single-pair High-speed Digital Subscriber Line Transceivers";     ⇒     In November,  publication of  $\text{ITU Recommendation G.993.1}$:  "Very-high-speed Digital Subscriber Line transceivers".

2002   First publications of  $\text{ITU Recommendations G.992.3}$:  "Asymmetric Digital Subscriber Line Transceivers 2"  $\rm (ADSL2)$  and  $\text{G.992.4}$:  "Splitterless ADSL2".

2003   First publication of  $\text{ITU Recommendation G.992.5}$:  "Asymmetric Digital Subscriber Line"  $\rm (ADSL)$  Transceivers"  and   "Extended-bandwidth ADSL2"  $\rm (ADSL2+)$.

02/2006   Publication of  $\text{ITU Recommendation G.993.2}$: "Very-high-speed Digital Subscriber Line Transceivers 2"  $\rm (VDSL2)$.

10/2006  Deutsche Telekom AG offers VDSL2 to end customers in selected cities for the first time.


Development of ADSL and VDSL in Europe


From the above compilation it can be seen that the  »ADSL standardization«  was predominantly driven by  $\rm ANSI$  $($"American National Standards Institute"$)$  and that  $\rm ETSI$  $($"European Telecommunications Standards Institute"$)$  followed shortly thereafter in each case:

  1. The first ADSL standard   "$\text{ANSI T1.413}$"   from 1995 was predominantly optimized for video-on-demand services,  which is also made clear by the ratio of the downstream and upstream data rates defined herein:  $1.5$  Mbit/s and  $16$  kbit/s,  $3$  Mbit/s and  $16$  kbit/s, and finally  $6$  Mbit/s and  $64$ kbit/s.
  2. The frequency range was originally defined in such a way that ADSL could only be used to operate an analog telephone on the access line.  ETSI published a technical report   "$\text{ETR 328}$"   in 1996 with only a few detailed changes and the possibility to transmit  $2048$  kbit/s.
  3. Since the second version of the ANSI standard also allowed only one additional analog telephone,  ETSI then defined an ADSL system that differed both in bit rates and in the possibility of using an ISDN basic access on the same twisted pair.
  4. The ANSI and ETSI standardization efforts of the previous years resulted in the  "ITU" recommendation  "$\text{G.992.1}$"   in 1999,  which includes both standards and thus allows many options for the implementation.


However,  the many options led to major conceptual differences at the end of the 1990s  –  worldwide,  within Europe and also nationally  –  depending on the semiconductor manufacturer,  among other things.  Only a few systems,  modems,  and measuring devices interoperated with other manufacturers.

To counteract this proliferation,  The  "Deutsche Telekom AG"  passed the technical guideline  "$\text{1TR112}$"   at the end of 2001,  defining all the necessary interface parameters to ensure the interoperability of different manufacturer modems on the provider and customer side. 

  • Due to Telekom's market power,  this became the quasi-standard for Germany.
  • Furthermore,  only those ADSL variants were used in Germany that allowed simultaneous operation of ISDN at any time.  Thus,  when switching from POTS to ISDN,  it was not necessary to change the ADSL version as well.


The  »VDSL standardization«  relevant for Europe was decisively shaped by ETSI and often happened in parallel to the American activities.  Overall,  VDSL standardization proceeded in a more orderly fashion than ADSL.  The 3-step plan adopted by ETSI provided for:

  • Stage 1:  Functional and electrical requirements for VDSL systems,
  • Stage 2:  Transmission coding and access method requirements,
  • Stage 3:  Interoperability requirements.


These efforts culminated in April 1998 in the publication of the ETSI Technical Specification  "$\text{TS 101 270-1}$",  which defines as modulation methods both  $\rm DMT$  $($"Discrete Multitone Transmission"$)$  and  $\rm QAM$  $($"Quadrature Amplitude Modulation"$)$.  The semiconductor manufacturers could not agree on a worldwide line code standard for a long time and there was even talk of the  "VDSL Line Code War".

In 2003,  at the so-called  "VDSL Olympics",  the decision was made in favor of DMT and against QAM or the slightly modified variant  $\rm CAP$  $($"Carrierless Amplitude Phase Modulation"$)$,  namely

  • because of the robustness of DMT against narrowband interference sources,
  • although QAM/ CAP would allow a faster call setup.



Exercises for the chapter


Exercise 2.1: General Description of xDSL