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

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{{Header
 
{{Header
 
|Untermenü=UMTS – Universal Mobile Telecommunications System
 
|Untermenü=UMTS – Universal Mobile Telecommunications System
|Vorherige Seite=Weiterentwicklungen des GSM
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|Vorherige Seite=Further Developments of the GSM
|Nächste Seite=UMTS–Netzarchitektur
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|Nächste Seite=UMTS Network Architecture
 
}}
 
}}
  
 
== # OVERVIEW OF THE FOURTH MAIN CHAPTER # ==
 
== # OVERVIEW OF THE FOURTH MAIN CHAPTER # ==
 
<br>
 
<br>
$\rm U$niversal $\rm M$obile $\rm T$elecommunications $\rm S$ystem (UMTS) ist ein Mobilfunksystem der dritten Generation, das bei seiner Einführung eine zukunftsweisende Alternative zu den bis dahin verwendeten Mobilfunksystemen darstellen sollte. Es bietet im Vergleich zu GSM nicht nur eine hochwertigere Sprachqualität, sondern dank seiner schnelleren und paketvermittelten Übertragung auch eine Vielfalt erweiterter Dienste und Funktionalitäten.
+
$\rm U$niversal&nbsp; $\rm M$obile&nbsp; $\rm T$elecommunications&nbsp; $\rm S$ystem&nbsp; $\rm (UMTS)$&nbsp; is a  third-generation mobile communications system,&nbsp; which,&nbsp; when it was introduced,&nbsp; was intended to be a forward-looking alternative to the mobile communications systems used until then.&nbsp; Compared with GSM,&nbsp; UMTS not only offers higher-quality speech,&nbsp; but also a variety of enhanced services and functionalities thanks to its faster and packet-switched transmission.
  
UMTS wurde Ende der 1990er Jahre im Rahmen einer Zusammenarbeit zwischen der&nbsp; ''International Telecommunication Union''&nbsp; (ITU) und dem 3GPP–Forum (''3rd Generation Partnership Project'') standardisiert und ist seit 2004 in Europa kommerziell verfügbar. In Deutschland wurden bis Ende 2007 mehr als 10 Millionen Nutzer registriert. Weltweit nutzen derzeit (2011) um die 200 Millionen Teilnehmer UMTS oder ähnliche Mobilfunksysteme der dritten Generation.
+
UMTS was standardized in the late 1990s as part of a collaboration between the&nbsp; "International Telecommunication Union"&nbsp; $\rm (ITU)$&nbsp; and the 3GPP Forum&nbsp; $($"3rd Generation Partnership Project"$)$&nbsp; and has been commercially available in Europe since 2004.  
  
Dieses Kapitel beinhaltet im Einzelnen:
+
&rArr; &nbsp; In 2011&nbsp; $($when this chapter was conceived$)$&nbsp; about 200 million subscribers worldwide were using UMTS or similar third-generation mobile communications systems. 
  
*UMTS als Mobilfunksystem der dritten Generation,
+
&rArr; &nbsp; In 2022&nbsp; $($when this chapter was revised again as part of the English translation$)$&nbsp; a global report by the network equipment industry has identified more than  hundred operators&nbsp; that have either completed 3G switch-off alongside 2G switch-off, &nbsp; are planning to do so or are in the process of doing so,&nbsp; in order to use the spectrum this frees up for&nbsp; [[Mobile_Communications/General_Information_on_the_LTE_Mobile_Communications_Standard| "LTE"]],&nbsp; "5G"&nbsp; or technology-neutral.  
*die Dienste und Sicherheitsaspekte in UMTS,
 
*die UMTS–Netzarchitektur,
 
*die physikalischen, logischen und Transportkanäle sowie deren Interaktionen,
 
*die zellulare Architektur in UMTS und deren Mechanismen,
 
*die in UMTS verwendete Sprach– und Kanalcodierung,
 
*die Bandspreizung und CDMA als Basis von UMTS,
 
*die Funkressourcenverwaltung und Leistungsregelung in UMTS–Netzen,
 
*die Weiterentwicklungen von UMTS wie HSDPA und HSUPA,
 
*ein Ausblick auf Long Term Evolution (LTE), dem Schlagwort der vierten Generation.  
 
  
 +
*28 operators in 17 countries and territories have now completed 3G switch-off.
  
Dem 4G–Standard&nbsp; [[Mobile_Communications/Allgemeines_zum_Mobilfunkstandard_LTE|Long Term Evolution]]&nbsp; (LTE) ist im Buch „Mobile Kommunikation” ein eigenes Kapitel gewidmet.
+
*Six operators in six countries and territories currently have 3G switch-off underway.
 +
 +
*Another 46 operators in 31 countries have 3G shutdowns planned for the very near future.  
  
 +
*It is also interesting to note from this report that in some countries the UMTS switch-off is being pushed even harder than that of the 2G standard&nbsp; [[Examples_of_Communication_Systems/General_Description_of_GSM| "GSM"]],&nbsp; which is about ten years older.
  
==Anforderungen an Mobilfunksysteme der dritten Generation==   
+
 
 +
&rArr; &nbsp; We have chosen to keep this chapter in our&nbsp; $\rm LNTwww$&nbsp; despite this negative forecast,&nbsp; since understanding the underlying CDMA technology also facilitates students' understanding of other communications engineering problems.
 +
 
 +
This chapter includes in detail:
 +
 
 +
#&raquo;UMTS&laquo;&nbsp;  as a third-generation mobile communications system,
 +
#the&nbsp; &raquo;services and security aspects&laquo;&nbsp; in UMTS,
 +
#the&nbsp; &raquo;UMTS network architecture&laquo;,
 +
#the&nbsp; &raquo;physical, logical and transport channels&laquo;&nbsp; and their interactions,
 +
#the&nbsp; &raquo;cellular architecture in UMTS&laquo;&nbsp; and its mechanisms,
 +
#the&nbsp; &raquo;speech and channel coding&laquo;&nbsp; used in UMTS,
 +
#the&nbsp; &raquo;band spreading and CDMA&laquo;&nbsp; as the basis of UMTS,
 +
#the&nbsp; &raquo;radio resource management and power control&laquo;&nbsp; in UMTS networks,
 +
#the&nbsp; &raquo;further developments of UMTS&laquo;&nbsp; such as&nbsp; &raquo;HSDPA&laquo;&nbsp; and&nbsp; &raquo;HSUPA&laquo;,
 +
#an outlook on&nbsp; &raquo;Long Term Evolution&laquo;&nbsp; $\rm (LTE)$,&nbsp; the buzzword of the fourth generation.
 +
 
 +
 
 +
==Requirements for third&ndash;generation mobile communications systems==   
 
<br>
 
<br>
Die wichtigste Motivation zur Entwicklung von&nbsp; ''Mobilfunksystemen der dritten Generation''&nbsp; war die Erkenntnis, dass die Systeme der zweiten Generation den Bandbreitenbedarf zur Nutzung multimedialer Dienste nicht zufrieden stellen konnten.  
+
The main motivation for the development of&nbsp; '''&raquo;third-generation mobile communications systems&laquo;'''&nbsp; was the realization that second-generation systems could not satisfy the bandwidth requirements for the use of multimedia services.
 +
 
 +
[[File:EN_Bei_T_4_1_S1.png|right|frame|Development of mobile communications systems from 1995 to 2006]]
 +
The graph shows the development of mobile radio systems since 1995 in terms of performance or data transmission rate as seen in 2007:
 +
*The specified data rates for HSUPA&nbsp; $($uplink,&nbsp; up to&nbsp; $\text{3 Mbit/s)}$&nbsp; and HSDPA&nbsp; $($downlink,&nbsp; up to&nbsp; $\text{7 Mbit/s)}$&nbsp; were realistic for 2006/2007.
 +
 
 +
*In contrast,&nbsp; the specifications stated maximum values for the uplink&nbsp; $\text{5.8 Mbit/s}$&nbsp; and for the downlink&nbsp; $\text{14.4 Mbit/s}$ $($i.e., significantly higher maximum values$)$,&nbsp; but these will probably not be achievable in practice.
 +
 
 +
*The third-generation mobile communications systems were to have greater bandwidth than the&nbsp; [[Examples_of_Communication_Systems/General_Description_of_GSM|"GSM"]]&nbsp; already established at that time and sufficient reserve capacity to ensure high quality of service even in the face of constantly growing demands.
 +
 
 +
*In the development of the 3G systems,&nbsp; the&nbsp; "International Telecommunication Union"&nbsp; $\rm (ITU)$&nbsp; has played an important role.&nbsp; Among other things,&nbsp; it created a catalog of requirements that defined their characteristics.  
  
[[File:P_ID1481__Bei_T_4_1_S1_v2.png|right|frame|Entwicklung der Mobilfunksysteme von 1995 bis 2006]]
 
Die Grafik zeigt die Entwicklung der Mobilfunksysteme seit 1995 hinsichtlich Leistungsfähigkeit bzw. Datenübertragungsrate aus Sicht des Jahres 2007:
 
* Die  angegebenen Datenraten  für HSUPA $($Uplink, bis&nbsp; $\text{3 Mbit/s)}$&nbsp; und HSDPA $($Downlink, bis&nbsp; $\text{7 Mbit/s)}$&nbsp; waren für 2006/2007 realistisch.
 
*In den Spezifikationen wurden dagegen für den Uplink&nbsp; $\text{5.8 Mbit/s}$ und für den Downlink&nbsp; $\text{14.4 Mbit/s}$ (also deutlich höhere Maximalwerte) genannt, die  in der Praxis wohl aber nicht erreichbar sein werden.
 
<br clear=all>
 
Die Mobilfunksysteme der dritten Generation sollten über eine größere Bandbreite als das damals bereits etablierte&nbsp; [[Examples_of_Communication_Systems/Allgemeine_Beschreibung_von_GSM|GSM]]&nbsp; verfügen und genügend Reserve an Leistungsfähigkeit aufweisen, um auch bei den stetig wachsenden Anforderungen eine hohe Dienstgüte gewährleisten zu können.
 
  
Bei der Entwicklung der Systeme der dritten Generation hat die&nbsp; ''International Telecommunication Union''&nbsp; (ITU) eine wichtige Rolle gespielt. Sie hat unter anderem einen Anforderungskatalog erstellt, der ihre Eigenschaften festlegte. Dieser Anforderungskatalog umfasst folgende Rahmenbedingungen:
+
This catalog of requirements includes the following general conditions:
*Hohe Datenraten von&nbsp; $\text{144 kbit/s}$ (Standard) bis&nbsp; $\text{2 Mbit/s}$&nbsp; (In-door),
+
#High data rates from&nbsp; $\text{144 kbit/s}$&nbsp; $($standard$)$&nbsp; to&nbsp; $\text{2 Mbit/s}$&nbsp; $($in-door$)$,
*symmetrische und asymmetrische Datenübertragung (IP–Dienste),
+
#symmetric and asymmetric data transmission&nbsp; $($IP services$)$,
*leitungsvermittelte (''circuit–switched'') und paketvermittelte (''packed–switched'') Übertragung,
+
#circuit-switched and packet-switched transmission,
*hohe Sprachqualität und hohe Spektraleffizienz,
+
#high speech quality and high spectral efficiency,
*nahtloser Übergang von und zu Systemen der zweiten Generation,
+
#seamless transition to and from second-generation systems,
*globale Erreichbarkeit und Verbreitung,
+
#global reachability and distribution,
*Anwendungen unabhängig vom verwendeten Netz (''Virtual Home Environment'').
+
#applications independent of the network used $($virtual home environment$)$.
  
 
 
 
 
==Der IMT–2000–Standard==   
+
==The IMT&ndash;2000 standard==   
 
<br>
 
<br>
Im Jahre 1992 wurde von der&nbsp; ''International Telecommuncation Union''&nbsp; (ITU) der Standard&nbsp; $\rm IMT\hspace{-0.1cm}-\hspace{-0.1cm}2000$&nbsp; $($''International Mobile Telecommunications at''&nbsp; 2000 MHz$)$&nbsp; ins Leben gerufen, der die genannten Anforderungen ermöglichen sollte. Dieser umfasst eine Reihe verschiedener Mobilfunksysteme der dritten Generation, die im Laufe der Standardisierung aneinander angenähert wurden, um die Entwicklung von gemeinsamen Endgeräten für alle diese Standards zu ermöglichen.
+
In 1992,&nbsp; the&nbsp; "International Telecommuncation Union"&nbsp; $\rm (ITU)$&nbsp; launched the&nbsp; $\text{IMT-2000}$&nbsp; $($"International Mobile Telecommunications at&nbsp; 2000 MHz"$)$&nbsp; standard to enable the above requirements.&nbsp; This comprises a number of different third-generation mobile communications systems that have been converged during the standardization process to enable the development of common terminals for all these standards.
 +
 
 +
In order to take into account nationally different preliminary work and to allow network operators to continue using existing network architectures to some extent,&nbsp;
 +
[[File:P_ID1482__Bei_T_4_1_S2_v1.png|right|frame|The "IMT family" &ndash; an overview]]
 +
 
 +
IMT&ndash;2000 includes several individual standards.&nbsp; These can be roughly divided into four categories:
 +
*$\rm W\hspace{-0.12cm}-\hspace{-0.08cm}CDMA$: &nbsp; This includes the FDD component of the European UMTS standard as well as the American&nbsp; "cdma2000"&nbsp; system.
 +
 
 +
*$\rm TD\hspace{-0.08cm}-\hspace{-0.08cm}CDMA$: &nbsp; This group includes the TDD component of UMTS as well as the Chinese&nbsp; "TD-SCDMA",&nbsp; which is now integrated into the&nbsp; "UMTS&ndash;TDD"&nbsp; standard.
 +
 
 +
*$\rm TDMA$: &nbsp; A further development of the GSM off-shoot&nbsp; "EDGE"&nbsp; and its American counterpart&nbsp; "UWC-136",&nbsp; also known as&nbsp; "DS-AMPS".
  
Um national unterschiedliche Vorarbeiten zu berücksichtigen und den Netzbetreibern die Möglichkeit zu geben, die bereits bestehenden Netzarchitekturen zum Teil weiter zu verwenden, beinhaltet IMT–2000 mehrere Einzelstandards. Diese lassen sich grob in vier Kategorien einteilen:
+
*$\rm FD\hspace{-0.08cm}-\hspace{-0.08cm}CDMA$: &nbsp; The further development of the European cordless telephony standard&nbsp; $\rm DECT$&nbsp; $($"Digital Enhanced Cordless Telecommunication"$)$.
[[File:P_ID1482__Bei_T_4_1_S2_v1.png|right|frame|Die  "IMT–Familie" &ndash; ein Überblick]]
 
*$\rm W–CDMA$: &nbsp;  Dazu zählt man die FDD-Komponente des europäischen UMTS–Standards sowie das amerikanische cdma2000–System.
 
*$\rm TD–CDMA$: &nbsp; Zu dieser Gruppe zählt die TDD–Komponente von UMTS sowie das chinesische TD–SCDMA, das mittlerweile in den UMTS–TDD–Standard integriert ist.
 
*$\rm TDMA$: &nbsp; Eine Weiterentwicklung des GSM–Ablegers EDGE und des amerikanischen Pendants UWC–136, auch bekannt als DS–AMPS.
 
*$\rm FD–TDMA$: &nbsp; Die Weiterentwicklung des europäischen Schnurlos–Telefonie–Standards DECT (''Digital Enhanced Cordless Telecommunication'').
 
  
  
Im Folgenden konzentrieren wir uns auf das in Europa entwickelte System&nbsp; $\rm UMTS$&nbsp; (''Universal Mobile Telecommunications System''), das die beiden erstgenannten Standards&nbsp; sowie&nbsp; $\rm TD–CDMA$&nbsp; der Systemfamilie IMT–2000 unterstützt.
+
In the following, &nbsp; we focus on the European-developed system&nbsp; $\rm UMTS$&nbsp; $($"Universal Mobile Telecommunications System"$)$, &nbsp; which supports the first two standards&nbsp; "$\rm W\hspace{-0.12cm}-\hspace{-0.08cm}CDMA$"&nbsp; and&nbsp; "$\rm TD\hspace{-0.08cm}-\hspace{-0.08cm}CDMA$"&nbsp; of the&nbsp; IMT&ndash;2000&nbsp; system family.
  
  
 
 
 
 
==Historische Entwicklung von UMTS ==  
+
==Historical development of UMTS ==  
 
<br>
 
<br>
Es folgen einige Daten zur historischen Entwicklung von UMTS und der verwendeten Techniken. Weitere Informationen finden Sie zum Beispiel unter diesem [http://www.umtsworld.com/umts/history.htm Internet–Link].
+
The following is some data on the historical development of UMTS and the techniques used.&nbsp; More information can be found,&nbsp; for example,&nbsp; at this [http://www.umtsworld.com/umts/history.htm "internet link"].
*'''1940–1950''' &nbsp; Erste militärische Anwendungen von Signalspreizverfahren.
+
*'''1940-1950''' &nbsp; First military applications of signal spreading techniques.
*'''1949''' &nbsp; Erste Grundzüge des CDMA–Verfahrens durch C. E. Shannon und J. R. Pierce.
+
 
*'''1970''' &nbsp; Verschiedene CDMA–Entwicklungen für militärische Systeme, z.B. GPS.
+
*'''1949''' &nbsp; First outlines of the CDMA process by C. E. Shannon and J. R. Pierce.
*'''1989–1992''' &nbsp; Grundlagenforschung zu den Eigenschaften zukünftiger Mobilfunksysteme im Rahmen des EU–Programms RACE–1 <br>(''Research, Analysis, Communication, Evaluation'').
+
 
*'''1992''' &nbsp; Erste Überlegungen zum Standard IMT–2000 durch die ITU.
+
*'''1970''' &nbsp; Various CDMA developments for military systems, e.g. GPS.
*'''1992–1995''' &nbsp; EU–Programm RACE–2 mit dem Schwerpunkt „Entwicklung von Systemkonzepten” – basierend auf den Ergebnissen von RACE–1.
 
*'''1996''' &nbsp; Gründung des UMTS–Forums in Zürich – Umbenennung des geplanten europäischen Standards „W–CDMA” in „UMTS”.
 
*'''1998''' &nbsp; Übernahme der beiden Modi ''W–CDMA'' und ''TD–CDMA'' in den UMTS–Standard auf der ETSI–SMG–Sitzung in Paris.
 
*'''1998''' &nbsp; Gründung des ''3gpp''–Forums (''3rd Generation Partnership Project'') durch die Gremien ETSI–SMG, T1P1, ARIB TTC und TTA.
 
*'''1999''' &nbsp; Verabschiedung des Standards UMTS–R99 (Release 1999) durch die ETSI. Dieser gilt als Basis für die ersten verfügbaren UMTS–Endgeräte.
 
*'''2001 '''&nbsp; Verabschiedung der Release 4 als Weiterentwicklung von UMTS–R99: ''Quality of Service'' (QoS) wird nun an der Funkschnittstelle und im Festnetz unterstützt.
 
*'''2001 '''&nbsp; Erstes kommerzielle UMTS–Netz des norwegischen Unternehmens TELENOR.
 
*'''2002 '''&nbsp; Verabschiedung der UMTS Release 5: &nbsp; Die an das GSM–Festnetz angelehnte Architektur wird durch ein vollständig IP–basiertes Festnetz ersetzt.
 
*'''2002 '''&nbsp; Erste UMTS–Sprach– und Datenverbindung von Nortel Networks und Qualcomm. Diese Firmen gelten als Vorreiter bei der Umsetzung der UMTS–Technologie.
 
*'''2004''' &nbsp; Verabschiedung der UMTS Release 6. Dieser Standard bietet dem Nutzer einen verbesserten QoS und dem Anbieter eine effektivere Ressourcenverwaltung.
 
  
 +
*'''1989-1992''' &nbsp; Basic research on the characteristics of future mobile radio systems within the EU program RACE-1&nbsp; $($Research,&nbsp; Analysis,&nbsp; Communication,&nbsp; Evaluation$)$.
  
[[File:P_ID1483__Bei_T_4_1_S3_v2_90.png|right|frame|Zur historischen Entwicklung von UMTS]]
+
*'''1992''' &nbsp; First consideration of the IMT-2000 standard by the ITU.
{{GraueBox|TEXT= 
 
$\text{Zusammenfassung der historischen Entwicklung von UMTS}$&nbsp;
 
  
 +
*'''1992-1995''' &nbsp; EU program RACE-2 focusing on "development of system concepts" - based on the results of RACE-1.
  
 +
*'''1996''' &nbsp; Foundation of the UMTS Forum in Zurich - renaming of the planned European standard&nbsp; "W-CDMA"&nbsp; to&nbsp; "UMTS".
  
Auch bei UMTS ist zwischen den ersten Konzeptüberlegungen und der endgültigen Einführung mehr als ein Jahrzehnt vergangen.  
+
*'''1998''' &nbsp; Adoption of the two modes&nbsp; "W-CDMA"&nbsp; and&nbsp; "TD-CDMA"&nbsp;' into the UMTS standard at the ETSI-SMG meeting in Paris.
  
 +
*'''1998''' &nbsp; Establishment of the&nbsp; "3gpp forum"&nbsp; $($"3rd Generation Partnership Project"$)$&nbsp; by the ETSI-SMG,&nbsp; T1P1,&nbsp; ARIB TTC&nbsp; and&nbsp; TTA committees.
  
Dies war ähnlich wie bei der Einführung anderer Kommunikationssysteme, wie zum Beispiel bei
+
*'''1999''' &nbsp; Adoption of the UMTS-R99 standard $($Release 1999$)$&nbsp; by ETSI.&nbsp; This is considered the basis for the first available UMTS terminals.
*[[Examples_of_Communication_Systems/Allgemeine_Beschreibung_von_ISDN|ISDN]]&nbsp; (''Integrated Services Digital Network''),
+
 
*[[Examples_of_Communication_Systems/Allgemeine_Beschreibung_von_DSL|DSL]]&nbsp; (''Digital Subscriber Line''),
+
*'''2001'''&nbsp; Adoption of Release 4 as a further development of UMTS-R99:&nbsp; "Quality of Service"&nbsp; $\rm (QoS)$&nbsp; is now supported at the radio interface and in the fixed network.
*[[Examples_of_Communication_Systems/Allgemeine_Beschreibung_von_GSM|GSM]]&nbsp; (''Global System for Mobile Communications'').}}
+
 
 +
*'''2001 '''&nbsp; First commercial UMTS network of the Norwegian company&nbsp; "TELENOR".
 +
 
 +
*'''2002 '''&nbsp; Adoption of UMTS Release 5: &nbsp; Architecture based on the GSM fixed network is replaced by a fully IP-based fixed network.
 +
 
 +
*'''2002 '''&nbsp; First UMTS speech and data link from&nbsp; "Nortel Networks"&nbsp; and&nbsp; "Qualcomm".&nbsp; These companies are considered pioneers in the implementation of UMTS.
 +
 
 +
*'''2004''' &nbsp; Adoption of UMTS Release 6,&nbsp; a standard that provides improved QoS for the user and more effective resource management for the provider.
 +
 
 +
 
 +
With UMTS, too,&nbsp; '''more than a decade has passed between the first conceptual considerations and the final introduction'''.
 +
 
 +
This was similar to the introduction of other communications systems,&nbsp; such as
 +
*[[Examples_of_Communication_Systems/General_Description_of_ISDN|"ISDN"]]&nbsp; $($"Integrated Services Digital Network"$)$,
 +
 
 +
*[[Examples_of_Communication_Systems/General_Description_of_DSL|"DSL"]]&nbsp; $($"'Digital Subscriber Line"$)$,
 +
 
 +
*[[Examples_of_Communication_Systems/General_Description_of_GSM|"GSM"]]&nbsp; $($"Global System for Mobile Communications"$)$.
 
<br clear=all>
 
<br clear=all>
 
==Frequency allocation for UMTS== 
 
==Frequency allocation for UMTS== 
 
<br>
 
<br>
Zuständig für die Zuweisung von Bandbreiten und Frequenzbänder der Kommunikationssysteme ist die&nbsp; ''International Telecommunication Union''&nbsp; (ITU). Insbesondere bei UMTS gibt es aber Abweichungen zwischen den europäischen und den ITU–Frequenzzuweisungen, da manche Frequenzbänder in manchen Ländern schon von anderen Mobilfunksystemen belegt waren. Die Grafik zeigt die europäische (unten) sowie die ITU–Frequenzbelegung (oben).
+
The&nbsp; International Telecommunication Union&nbsp; $\rm (ITU)$&nbsp; is responsible for allocating bandwidths and frequency bands for communications systems.&nbsp; In the case of UMTS in particular,&nbsp; however,&nbsp; there are discrepancies between the European and ITU frequency allocations,&nbsp; as some frequency bands were already occupied by other mobile communications systems in some countries.&nbsp;
 +
[[File:EN_Bei_T_4_1_S4.png|right|frame|UMTS frequency spectra]]
 +
 
 +
The graph shows the European&nbsp; $($bottom$)$&nbsp; and the ITU frequency assignments&nbsp; $($top$)$.&nbsp; Meaning:
 +
 
 +
$\rm GSM \ 1800$: <br>Frequency band for the downlink of GSM 1800,
 +
 
 +
$\rm SAT$: <br>Satellite-based systems &nbsp; $($each&nbsp; $\text{30 MHz}$&nbsp; for uplink and downlink$)$,
 +
 
 +
$\rm DECT$: <br>Digital Enhanced Cordless Telecommunications,
 +
 
 +
$\rm UTRA\:FDD$, &nbsp; for short: &nbsp; $\rm FDD$: <br>UMTS Terrestrial Radio Access&nbsp; &ndash; &nbsp;Frequency Division Duplex,
 +
 
 +
$\rm UTRA\:TDD$, &nbsp; for short: &nbsp; $\rm TDD$: <br>UMTS Terrestrial Radio Access&nbsp; &ndash; &nbsp;Time Division Duplex.
  
[[File:P_ID1526__Bei_T_4_1_S4_v1.png|right|frame|UMTS&ndash;Frequenzspektren]]
+
 
Hierbei bedeuten:
+
<u>Note:</u>
*$\rm GSM \ 1800$ – Frequenzband für den Downlink des GSM 1800,
+
 
*$\rm SAT$ – satellitengestützte Systeme <br>(jeweils&nbsp; $\text{30 MHz}$&nbsp; für Uplink und Downlink),
+
&rArr; &nbsp; $\rm FDD$&nbsp; consists of twelve paired uplink and downlink frequency bands of&nbsp; $\text{5 MHz}$&nbsp; bandwidth each. The frequency bands are located in Europe between
*$\rm DECT$ – ''Digital Enhanced Cordless Telecommunications'' <br>(Schnurlostelefon– Standard),
+
*&nbsp; $\text{1920 MHz}$&nbsp; and&nbsp; $\text{1980 MHz}$&nbsp; in the uplink,
*$\rm UTRA–FDD$ – ''UMTS Terrestrial Radio Access–Frequency Division Duplex'',
+
*$\rm UTRA–TDD$ – ''UMTS Terrestrial Radio Access–Time Division Duplex''.
+
*&nbsp; $\text{2110 MHz}$&nbsp; and&nbsp; $\text{2170 MHz}$&nbsp; in the downlink.
<br clear=all>
 
$\rm UTRA–FDD$&nbsp; &ndash; oder kurz&nbsp; $\rm FDD$&nbsp; &ndash;  besteht aus zwölf gepaarten Uplink– und Downlink–Frequenzbändern zu je&nbsp; $\text{5 MHz}$&nbsp; Bandbreite. Die Frequenzbänder liegen in Europa
 
*zwischen&nbsp; $\text{1920 MHz}$&nbsp; und&nbsp; $\text{1980 MHz}$&nbsp; im Uplink, sowie
 
*zwischen&nbsp; $\text{2110 MHz}$&nbsp; und&nbsp; $\text{2170 MHz}$&nbsp; im Downlink.
 
  
  
Dagegen besteht&nbsp; $\rm UTRA–TDD$&nbsp;  &ndash;  oder kurz $\rm TDD$ &ndash; aus fünf Frequenzbändern zu je&nbsp; $\text{5 MHz}$&nbsp; Bandbreite, in denen mittels Zeitmultiplex sowohl Uplink– als auch Downlink–Daten übertragen werden sollen.  
+
&rArr; &nbsp;  $\rm TDD$&nbsp; consists of five frequency bands of&nbsp; $\text{5 MHz}$&nbsp; bandwidth each,&nbsp; in which both uplink and downlink data are to be transmitted using time division multiplexing.  
*Für TDD sind die Frequenzen zwischen&nbsp; $\text{1900 MHz}$&nbsp; und&nbsp; $\text{1920 MHz}$&nbsp; (vier Kanäle) und zwischen&nbsp; $\text{2020 MHz}$&nbsp; und&nbsp; $\text{2025 MHz}$&nbsp; (ein Kanal) reserviert.  
+
*The TDD band lies between&nbsp; $\text{1900 MHz}$&nbsp; and&nbsp; $\text{1920 MHz}$&nbsp; $($four channels$)$&nbsp; and between&nbsp; $\text{2020 MHz}$&nbsp; and&nbsp; $\text{2025 MHz}$&nbsp; $($one channel$)$.
*Das Band zwischen&nbsp; $\text{2010 MHz}$&nbsp; und&nbsp; $\text{2020 MHz}$&nbsp; wurde noch nicht lizenziert und wird deswegen in Deutschland ebenfalls noch nicht genutzt.
+
 +
*The band between&nbsp; $\text{2010 MHz}$&nbsp; and&nbsp; $\text{2020 MHz}$&nbsp; has not been licensed in 2007.
  
 
   
 
   
== Vollduplexverfahren ==
+
== Full duplex ==
 
<br>
 
<br>
Um die beiden Übertragungsrichtungen Uplink und Downlink zu trennen, werden in UMTS zwei unterschiedliche Betriebsmodi unterstützt. Man unterscheidet:
+
In order to separate the two transmission directions uplink and downlink,&nbsp; two different operating modes are supported in UMTS.&nbsp; A distinction is made between:
*''UMTS Terrestrial Radio Access Frequency Division Duplex''&nbsp; (UTRA–FDD),
+
:'''&raquo;UMTS Terrestrial Radio Access Frequency Division Duplex&laquo;'''&nbsp; $\rm (UTRA\hspace{-0.08cm}-\hspace{-0.08cm}FDD)$,
*''UMTS Terrestrial Radio Access Time Division Duplex''&nbsp; (UTRA–TDD).
+
 
 +
:'''&raquo;UMTS Terrestrial Radio Access Time Division Duplex&laquo;'''&nbsp; $\rm (UTRA\hspace{-0.08cm}-\hspace{-0.08cm}TDD)$,<br><br>
 +
 
 +
*The main difference between these two modes can be seen in the physical layer of the protocol stack.  
  
 +
*The two methods differ in both their duplex and multiple access methods.
  
Der wesentliche Unterschied zwischen diesen beiden Modi zeigt sich vor allem in der physikalischen Ebene des Protokollstapels. Die beiden Verfahren unterscheiden sich dabei sowohl in ihren Duplex– als auch in ihren Vielfachzugriffsverfahren.
 
  
[[File:P_ID1527__Bei_T_4_1_S3a_v1.png|center|frame|UTRA–FDD–Modus in UMTS]]
+
[[File:P_ID1527__Bei_T_4_1_S3a_v1.png|right|frame|UTRA-FDD mode in UMTS]]
  
Im&nbsp; $\rm UTRA–FDD$–Modus werden – wie in obiger Grafik zu sehen – die Uplink– und Downlink–Daten gleichzeitig auf unterschiedlichen, aber korrespondierenden gepaarten Frequenzblöcken zu je&nbsp; $\text{5 MHz}$&nbsp; übertragen. Dabei ist zu beachten:
+
In the &nbsp; $\rm UTRA\hspace{-0.08cm}-\hspace{-0.08cm}FDD$&nbsp; mode,&nbsp;  as shown in the graph on the right:
*Daten verschiedener Teilnehmer werden auf dem gleichen Frequenzband gesendet und empfangen.  
+
# Uplink and downlink data are transmitted simultaneously on different but corresponding paired&nbsp; $\text{5 MHz}$&nbsp; frequency blocks.  
*Die Verwendung von verschiedenen CDMA–Spreizcodes ermöglicht die Trennung der jeweiligen Teilnehmerdaten.
+
#Data from different subscribers are transmitted and received on the same frequency band.  
*Es wird außerdem das&nbsp; ''TDMA–Verfahren''&nbsp; verwendet, um periodische Funktionen wie zum Beispiel die Leistungssteuerung zu realisieren.
+
#The use of different CDMA spreading codes enables the separation of the respective subscriber data.
*Das&nbsp; ''FDMA–Verfahren''&nbsp; kann zusätzlich zu CDMA und TDMA genutzt werden, wenn der Netzbetreiber über mehr als einen Frequenzkanal verfügt.
+
#The&nbsp; TDMA method&nbsp; is also used to realize periodic functions such as power control.
 +
#The&nbsp; FDMA method&nbsp; can be used in addition to CDMA and TDMA if the network operator has more than one frequency channel.
  
  
Der FDD–Modus wird nur in Europa und meist nur bei symmetrischen Diensten verwendet, deren Bandbreitenanforderungen im Uplink und im Downlink etwa gleich sind. Dies ist zum Beispiel bei der Sprachkommunikation oder der Videotelefonie der Fall.
+
FDD mode is used only in Europe and mostly only for symmetrical services whose bandwidth requirements in the uplink and downlink are approximately the same.&nbsp; This is the case for speech communications or video telephony,&nbsp; for example.
 
   
 
   
  
Im&nbsp; $\rm UTRA–TDD$–Modus werden Uplink– und Downlink–Daten im gleichen Frequenzband übertragen. Dabei werden Uplink und Downlink zeitlich getrennt, wie die folgende Grafik zeigt. Weiterhin gilt:
+
[[File:P_ID1528__Bei_T_4_1_S3b_v1.png|right|frame|UTRA TDD mode in UMTS]]
*Der Umschaltzeitpunkt (''Switching Point'') kann abhängig vom Datenvolumenverhältnis zwischen Uplink und Downlink flexibel gewählt werden.
+
In the &nbsp; $\rm UTRA\hspace{-0.08cm}-\hspace{-0.08cm}TDD$&nbsp; mode,&nbsp; uplink and downlink data are transmitted in the same frequency band.&nbsp; In this case,&nbsp; uplink and downlink are separated in time,&nbsp; as shown in the following diagram. Furthermore:
*Die Teilnehmer werden beim TDD–Modus sowohl durch den Spreizcode&nbsp; (wie bei FDD)&nbsp; als auch durch den Zeitschlitz gekennzeichnet.
+
#The&nbsp; "switching point"&nbsp; can be flexibly selected depending on the data volume ratio between uplink and downlink.
*Verfügt der Netzbetreiber mehrere Frequenzkanäle, so kann wie bei FDD  zusätzlich zu CDMA und TDMA noch FDMA zum Einsatz kommen.
+
#In TDD mode,&nbsp; the subscribers are identified both by the spreading code&nbsp; $($as in FDD$)$&nbsp; and by the time slot.
 +
#If the network operator has several frequency channels,&nbsp; FDMA can be used in addition to CDMA and TDMA as with FDD.
  
[[File:P_ID1528__Bei_T_4_1_S3b_v1.png|center|frame|UTRA–TDD–Modus in UMTS]]
 
 
Der TDD–Modus wird derzeit in Europa noch nicht genutzt und wird nach seiner Einführung hauptsächlich bei asymmetrischen Diensten (zum Beispiel: &nbsp; Downloads oder Surfen im Internet) eingesetzt werden, bei denen sich die Datenvolumina von Downlink und Uplink deutlich unterscheiden.
 
  
 +
TDD mode was 2007 not used in Europe and,&nbsp; once introduced,&nbsp; will mainly be used for asymmetric services&nbsp;  where the data volumes of downlink and uplink differ significantly.
 +
<br clear=all>
  
 
==Properties of the UMTS radio channel==   
 
==Properties of the UMTS radio channel==   
 
<br>
 
<br>
Im UMTS–Funkkanal treten neben Interferenzen durch andere Teilnehmer und Rauschen zusätzlich eine Reihe unvorhersehbarer, störender und verzerrender Effekte auf, die sich zudem über der Zeit verändern.  
+
In the UMTS radio channel,&nbsp; in addition to interference from other subscribers and noise,&nbsp; a number of unpredictable,&nbsp; interfering and distorting effects occur,&nbsp; which also change over time.
 +
 
 +
[[File:EN_Mob_T1_1_S1.png|right|frame|Example for a mobile radio scenario|class=fit]]
 +
&rArr; &nbsp; Due to reflections as well as scattering and diffraction from objects,&nbsp;  the transmitted signal experiences&nbsp; '''&raquo;multipath propagation&laquo;'''.
 +
 
 +
*The signal reaches the receiver not only via the direct path,&nbsp; but via several paths with different propagation times and different attenuation.
 +
 
 +
*The multipath scattering is influenced by the environment,&nbsp; but additionally also by a possible movement of the user,&nbsp; as indicated in the graph by the movement speed&nbsp; $v$.
 +
 
 +
 
 +
&rArr; &nbsp; The&nbsp; '''path loss''' goes back to propagation properties of electromagnetic waves &ndash; see page&nbsp; [[Mobile_Communications/Distance_Dependent_Attenuation_and_Shading#Common_path_loss_model|"common path loss model"]]&nbsp; in the book&nbsp; "Mobile Communication".&nbsp; For the study of this attenuation phenomenon,&nbsp; we assume a simplified path loss model.&nbsp; This states:
 +
*The received power of a radio signal decreases with distance&nbsp; $d$&nbsp; by&nbsp; $d^{-γ}$,&nbsp; where&nbsp; $γ$ &nbsp; is a medium-dependent constant of the radio propagation wave.
 +
 
 +
*Accounting for constructive or destructive ground reflections,&nbsp; the constant&nbsp; $γ$ &nbsp; below the&nbsp; "break point"&nbsp; $d_0$&nbsp; takes values between&nbsp; $2$&nbsp; and&nbsp; $3$.
 +
 
 +
*Above this characteristic point,&nbsp; the reflection effects increase and the propagation constant&nbsp; $γ$ &nbsp; grows to values between&nbsp; $3.5$&nbsp; and&nbsp; $4$.
 +
 
 +
 
 +
{{GraueBox|TEXT=
 +
$\text{Example 1:}$&nbsp;
 +
Shown on the right is the path loss&nbsp; $($in dB$)$&nbsp; as a function of the distance&nbsp; $d$&nbsp; $($in meter$)$.
 +
[[File:EN_Bei_T_4_1_S2_neu.png|right|frame|Path loss&nbsp; $($attenuation$)$&nbsp; as a function of the distance]]
 +
In this example,
 +
*the constant&nbsp; $α_0 = 10^{-5}$&nbsp; is set &nbsp; &rArr; &nbsp; $10 \cdot \lg \ α_0 = 50 \ \rm dB$,
 +
 
 +
*the break point is at&nbsp; $d_0 = \ \rm 100 \ m$.
 +
 
 +
 
 +
 
 +
 
  
Bedingt durch Reflexionen sowie Streuungen und Beugungen an Objekten erfährt das gesendete Signal eine&nbsp; '''Mehrwegeausbreitung'''&nbsp; (englisch:&nbsp; ''Mulipath Scattering'').
 
  
[[File:P_ID1529__Bei_T_4_1_S5a_v2.png|right|frame|Szenario mit Mehrwegeausbreitung]]
 
*Dabei erreicht das Signal den Empfänger nicht nur über den direkten Pfad, sondern über mehrere Wege mit unterschiedlichen Laufzeiten und unterschiedlich gedämpft.
 
*Die Mehrwegeausbreitung wird von der Umgebung beeinflusst, zusätzlich aber auch von einer möglichen Bewegung des Teilnehmers, wie in der Grafik durch die Bewegungsgeschwindigkeit&nbsp; $v$&nbsp; angedeutet ist.
 
<br clear=all>
 
Der&nbsp; '''Pfadverlust'''&nbsp; (englisch:&nbsp; ''Path–Loss'') geht auf Ausbreitungseigenschaften elektromagnetischer Wellen zurück – siehe Seite&nbsp; [[Mobile_Communications/Distanzabhängige_Dämpfung_und_Abschattung#Gebr.C3.A4uchliches_Pfadverlustmodell|Gebräuchliches Pfadverlustmodell]]&nbsp; im Buch "Mobile Kommunikation". Für die Untersuchung dieses Dämpfungsphänomens gehen wir von einem vereinfachten Pfadverlustmodell aus. Dieses besagt:
 
*Die Empfangsleistung eines Funksignals fällt mit der Entfernung&nbsp; $d$&nbsp; um&nbsp; $d^{–γ}$, wobei&nbsp; $γ$&nbsp; eine mediumsabhängige Konstante der Funkausbreitungswelle darstellt.
 
*Unter Berücksichtigung von konstruktiven oder destruktiven Bodenreflexionen nimmt die Konstante&nbsp; $γ$&nbsp; unterhalb des&nbsp; "Break Points"&nbsp; $d_0$&nbsp; Werte zwischen&nbsp; $2$&nbsp; und&nbsp; $3$&nbsp; an.
 
*Oberhalb dieses charakteristischen Punktes verstärken sich die Reflexionseffekte und die Ausbreitungskonstante&nbsp; $γ$&nbsp; wächst auf Werte zwischen&nbsp; $3.5$&nbsp; und&nbsp; $4$&nbsp; an.
 
  
  
[[File:P_ID1530__Bei_T_4_1_S5b_v1.png|right|frame|Pfadverlust (Dämpfung) abhängig von der Entfernung]]
+
One can see from the graph:
{{GraueBox|TEXT= 
+
#In the left-hand range&nbsp; $(d \ll d_0)$&nbsp; holds&nbsp; $γ \approx 2$<br><br>
$\text{Beispiel 1:}$&nbsp;
+
#For&nbsp; $d \gg d_0$&nbsp; on the other hand:&nbsp; $γ \approx 4$.<br><br>
Rechts dargestellt ist der Pfadverlust (in dB) in Abhängigkeit der Entfernung&nbsp; $d$. Bei diesem Beispiel ist die Konstante&nbsp; $α_0 = 10^{–5}$&nbsp; $($also&nbsp; $50 \ \rm dB)$&nbsp; gesetzt und der Break Point liegt bei&nbsp; $d_0 = \ \rm 100 \ m$.
+
#In the region around&nbsp; $d = d_0$:&nbsp; <br>The propagation constant increases continuously from&nbsp; $γ = 2$ &nbsp; to&nbsp; $γ = 4$. }}
*Im linken Bereich&nbsp;  $(d \ll d_0)$&nbsp; gilt&nbsp; $γ \approx 2$.
 
*Für&nbsp; $d \gg d_0$&nbsp; ist dagegen&nbsp; $γ \approx 4$.  
 
*Im Bereich um&nbsp; $d = d_0$&nbsp; steigt die Ausbreitungskonstante koninuierlich von&nbsp;   $γ = 2$&nbsp; auf&nbsp; $γ = 4$&nbsp; an.}}
 
 
 
 
 
  
==Frequenz&ndash; und zeitselektives Fading==   
+
==Frequency&ndash;selective and time&ndash;selective fading==   
 
<br>
 
<br>
Eine wesentliche Eigenschaft des Mobilfunkkanals stellt das so genannte&nbsp; '''Fading'''&nbsp; dar. Dieses entsteht durch zeitlich veränderliche Signalabschattungen&nbsp; (englisch:&nbsp; ''Shadowing'')&nbsp; und durch mögliche Bewegungen des Mobilfunkteilnehmers.
+
An essential property of the mobile radio channel is the so-called &nbsp; '''&raquo;fading&laquo;'''.&nbsp; This is caused by time-varying shadowing and by possible movements of the mobile subscriber.&nbsp; In the book&nbsp; "[[Mobile_Communications/Probability_Density_of_Rayleigh_Fading#Frequency-selective_fading_vs._non-frequency-selective_fading|Mobile Communications]]"&nbsp; this type of signal degradation is discussed in detail.  
  
Im Buch&nbsp; [[Mobile Kommunikation]]&nbsp; wird diese Art der Signalbeeinträchtigung ausführlich behandelt.  
+
Here follows only a brief summary.&nbsp; One distinguishes on the one hand:
 +
*'''&raquo;Short term fading&laquo;'''&nbsp; or&nbsp; "fast fading"&nbsp; &nbsp; &rArr; &nbsp; short term drops  in the received power &nbsp; $($mostly in the microseconds range$)$.
  
Hier folgt nur eine kurze Zusammenfassung. Man unterscheidet zum einen:
+
*'''&raquo;Long term fading&laquo;'''&nbsp; or&nbsp; "slow fading" &nbsp; &rArr; &nbsp; only slow changes&nbsp; $($mostly in the seconds range$)$.
*''schnelles Fading''&nbsp; (englisch:&nbsp; ''Fast Fading''&nbsp; oder&nbsp; ''Short Term Fading'')&nbsp; mit kurzzeitigen Einbrüchen der Empfangsleistung im Mikrosekundenbereich,
 
*''langsames Fading''&nbsp; (englisch:&nbsp; ''Long Term Fading'')&nbsp; – also nur langsame Veränderungen (meist) im Sekundenbereich.
 
  
 +
::Fast fading mainly affects systems with large symbol durations,&nbsp; i.e.&nbsp; small bandwidths.&nbsp; However,&nbsp; since the bandwidth of UMTS is much larger than that of GSM,&nbsp; this system is less susceptible to fast fading.
  
''Fast Fading''&nbsp; beeinträchtigt hauptsächlich Systeme mit großer Symboldauer, also kleiner Bandbreite. Da aber die Bandbreite bei UMTS sehr viel größer ist als bei GSM, ist dieses System weniger anfällig gegenüber ''Fast Fading''.
+
Furthermore,&nbsp; fading can also be classified as follows:
 +
*'''&raquo;Frequency-selective fading&laquo;'''&nbsp; is caused by multipath propagation over paths with different delay times. <br> &nbsp; &nbsp; As a result of this fading,&nbsp; different frequency components are attenuated differently by the power transfer function&nbsp; $|H_{\rm K}(f)|^2$&nbsp; of the channel.
  
Weiterhin lässt sich Fading auch noch wie folgt klassifizieren:
+
*'''&raquo;Time-selective fading&laquo;'''&nbsp; occurs due to a relative motion between transmitter and receiver. <br> &nbsp; &nbsp; This causes frequency shifts depending on the direction of movement&nbsp; $($towards or away from the transmitter$)$&nbsp; which are physically described by the&nbsp; [[Mobile_Communications/Statistical_Bindings_within_the_Rayleigh_Process#Phenomenological_description_of_the_Doppler_effect|"Doppler effect"]].
*'''Frequenzselektives Fading'''&nbsp; wird durch Mehrwegeausbreitung über Pfade mit unterschiedlichen Verzögerungszeiten verursacht. Als Folge dieses Fadings werden verschiedene Frequenzanteile durch die Leistungsübertragungsfunktion&nbsp; $|H_{\rm K}(f)|^2$&nbsp; des Kanals unterschiedlich gedämpft.
 
*'''Zeitselektives Fading'''&nbsp; entsteht durch eine Relativbewegung zwischen Sender und Empfänger. Dadurch kommt es abhängig von der Bewegungsrichtung&nbsp; (hin zum oder weg vom Sender)&nbsp; zu Frequenzverschiebungen, die physikalisch durch den&nbsp; ''Dopplereffekt''&nbsp; beschrieben werden.
 
  
 +
::The fading characteristics&nbsp; "frequency selective"&nbsp; and&nbsp; "time selective"&nbsp; shall now be explained in more detail,&nbsp; in particular it will be explained under which conditions which of these fading types are to be expected.&nbsp; At this point we also refer to two e-learning tools:
 +
::# HTML5/JavaScript applet&nbsp; [[Applets:The_Doppler_Effect|"The Doppler effect"]],
 +
::# German language SWF applet&nbsp; [[Applets:Multipath_propagation_and_frequency_selectivity_(Applet)|"Multipath propagation and frequency selectivity"]].
  
Die Fadingeigenschaften&nbsp; "frequenzselektiv"&nbsp; und&nbsp; "zeitselektiv"&nbsp; sollen nun noch etwas genauer erläutert werden, insbesondere wird dargelegt, unter welchen Bedingungen mit welchen dieser Fadingarten zu rechnen ist. Wir verweisen an dieser Stelle auch auf die beiden interaktiven Applets
+
{{BlaueBox|TEXT=  
:: [[Applets:Mehrwegeausbreitung_und_Frequenzselektivität_(Applet)|Mehrwegeausbreitung und Frequenzselektivität]]&nbsp; sowie
+
$\text{Characteristics of frequency-selective fading:}$&nbsp;
:: [[Applets:Zur_Verdeutlichung_des_Dopplereffekts_(Applet)|Zur Verdeutlichung des Dopplereffekts]].
+
*Receiving different scattering components with different delay times results in a&nbsp; '''&raquo;delay spread&laquo;'''&nbsp;  $T_{\rm V}$, defined as the difference between maximum and minimum delay times&nbsp; $($ German:&nbsp; "Verzögerungszeiten &nbsp; &rArr; &nbsp; subscript "V"$)$.&nbsp; The inverse of this gives approximately the&nbsp; '''&raquo;coherence bandwidth&laquo;'''&nbsp; $B_{\rm K}$.
  
{{BlaueBox|TEXT= 
+
*It is called&nbsp; "frequency-selective fading"&nbsp; if the coherence bandwidth&nbsp; $B_{\rm K}$&nbsp; is much smaller than the signal bandwidth&nbsp; $B_{\rm S}$.&nbsp; As a result,&nbsp; different frequency components are attenuated differently by the channel,&nbsp; resulting in linear distortions.}}
$\text{Kennzeichen von  frequenzselektivem Fading:}$&nbsp;
 
*Durch den Empfang verschiedener Streukomponenten mit unterschiedlichen Verzögerungszeiten entsteht eine&nbsp; '''Mehrwegeverbreiterung'''&nbsp; (englisch:&nbsp; ''Delay Spread''&nbsp;)&nbsp; $T_{\rm V}$, definiert als Differenz zwischen maximaler und minimaler Verzögerungszeit. Der Kehrwert hiervon ergibt näherungsweise die Kohärenzbandbreite&nbsp; $B_{\rm K}$.
 
*Man spricht dann von&nbsp; ''frequenzselektivem Fading'', wenn die Kohärenzbandbreite&nbsp; $B_{\rm K}$&nbsp; sehr viel kleiner ist als die Signalbandbreite&nbsp; $B_{\rm S}$. Als Folge werden verschiedene Frequenzanteile durch den Kanal unterschiedlich gedämpft, woraus lineare Verzerrungen resultieren.}}
 
  
  
{{BlaueBox|TEXT=   
+
{{BlueBox|TEXT=   
$\text{Kennzeichen von  zeitselektivem Fading:}$&nbsp;  
+
$\text{Characteristics of time-selective fading:}$&nbsp;  
*Beim zeitselektiven Fading entsteht eine so genannte&nbsp; '''Dopplerverbreiterung'''&nbsp; (englisch:&nbsp; ''Doppler Spread''&nbsp;)&nbsp; $B_{\rm D}$, die als Differenz zwischen der maximal und der minimal auftretenden Dopplerfrequenz definiert ist.  
+
*In&nbsp; "time-selective fading",&nbsp;  a so-called&nbsp; '''&raquo;Doppler spread&laquo;'''&nbsp; $B_{\rm D}$&raquo; occurs,&nbsp; which is defined as the difference between maximum and minimum Doppler frequencies.
*Deren Kehrwert bezeichnet man als die&nbsp; ''Korrelationsdauer''&nbsp; $T_{\rm D} = {1}/{B_{\rm D} }$. In manchen Literaturstellen wird diese Größe auch als&nbsp; ''Kohärenzzeit''&nbsp; bezeichnet. Bei UMTS tritt immer dann&nbsp; ''zeitselektives Fading''&nbsp; auf, wenn die&nbsp; ''Korrelationsdauer''&nbsp; $T_{\rm D}$&nbsp; sehr viel kleiner ist als die Chipdauer&nbsp; $T_{\rm C}$.}}  
+
 +
*The reciprocal of which is called the&nbsp; "correlation time"&nbsp; $T_{\rm D} = {1}/{B_{\rm D} }$.&nbsp; In some literatures,&nbsp; this quantity is also referred to as&nbsp; "coherence time".&nbsp; In UMTS,&nbsp; "time-selective fading"&nbsp; occurs whenever the correlation time&nbsp; $T_{\rm D}$&nbsp; is much smaller than the chip duration&nbsp; $T_{\rm C}$.}}  
  
  
{{GraueBox|TEXT=
+
{{GraueBox|TEXT=  
$\text{Beispiel 2:}$&nbsp;
+
$\text{Example 2:}$&nbsp;
Die linke Grafik verdeutlicht den Unterschied zwischen frequenzselektivem und nicht frequenzselektivem Fading:
+
The left graph illustrates the difference between frequency-selective and non-frequency-selective fading:
[[File:P_ID1531__Bei_T_4_1_S7_v1.png|right|frame|Die roten Kurven verdeutlichen frequenzselektives und zeitselektives Fading]]  
+
[[File:EN_Bei_T_4_1_S7_v3.png|right|frame|The red curves illustrate frequency-selective and time-selective fading]]  
*Dargestellt ist die Leistungsübertragungsfunktion&nbsp; $\vert H_{\rm K}(f, t)\vert ^2$&nbsp; des Kanals zu einer festen Zeit&nbsp; $t$.  
+
#Shown in this graph is the logarithm power transfer function&nbsp; $\vert H_{\rm K}(f,\ t)\vert ^2$&nbsp; of the channel at a fixed time&nbsp; $t$.  
*Während blau nichtfrequenzselektives Fading mit&nbsp; $-5 \ \rm dB$&nbsp; eingezeichnet ist, zeigt die rote Kurve in der linken Grafik ein Beispiel von frequenzselektivem Fading.
+
#While non-frequency-selective fading is plotted in blue with&nbsp; $-5 \ \rm dB$&nbsp;, the red curve shows an example of frequency-selective fading.
*Unterschiedliche Frequenzanteile werden dabei unterschiedlich gedämpft.
+
#Different frequency components are thereby attenuated differently.
  
  
  
Die rechte Grafik zeigt schematisch zeitselektives Fading:  
+
The right graph shows schematically&nbsp; "time-selective fading":  
*Aufgetragen ist hier die Leistungsübertragungsfunktion&nbsp; $\vert H_{\rm K}(f, t) \vert ^2$&nbsp; des Kanals für eine feste Frequenz&nbsp; $f$.  
+
#Here,&nbsp; the power transfer function&nbsp; $\vert H_{\rm K}(f,\ t) \vert ^2$&nbsp; of the channel for a fixed frequency&nbsp; $f$ is plotted.  
*Die blaue Kurve gilt für nicht zeitselektives Fading: &nbsp;Zu jeder Zeit wird das Signal um&nbsp; $5 \ \rm dB$&nbsp; gedämpft.}}
+
#The blue curve is valid for non-time-selective fading: &nbsp;At any time the signal is attenuated by&nbsp; $5 \rm dB$&nbsp;. }}
 
 
 
 
  
==UMTS–Dienste ==
+
==UMTS services ==
 
<br>
 
<br>
Die Einführung von UMTS hat sich unter anderem die Erweiterung und Diversifikation der angebotenen Mobilfunkdienste zum Ziel gesetzt. Ein UMTS–fähiges Endgerät muss zusätzlich zu den klassischen Diensten (Sprachübertragung, Messaging, usw.) eine Reihe komplexerer multimedialer Anwendungen und Funktionen unterstützen.
+
One of the goals of the introduction of UMTS is to expand and diversify the mobile communications services offered.&nbsp; A UMTS capable terminal must support a number of more complex multimedia applications and functions in addition to the classic services&nbsp; $($speech transmission,&nbsp; messaging, ...$)$.
 +
 
 +
These services can be divided into six main categories,&nbsp; depending on the application:
 +
#'''Information'''&nbsp;: &nbsp; Internet surfing&nbsp; $($info-on-demand$)$,&nbsp; online print media,
 +
#'''Communication''': &nbsp; Video and audio conferencing,&nbsp; fax,&nbsp; ISDN,&nbsp; messaging,
 +
#'''Entertainment''': &nbsp; Mobile TV,&nbsp; mobile radio,&nbsp; video-on-demand,&nbsp; online gaming,
 +
#'''Business''': &nbsp; Interactive shopping,&nbsp; e-commerce,
 +
#'''Technical area''': &nbsp; Online support,&nbsp; distribution service&nbsp; $($speech and data$)$,
 +
#'''Medical area''': &nbsp; Telemedicine.
  
Man kann diese Dienste – je nach Anwendung – in sechs Hauptkategorien unterteilen:
 
*''Information''&nbsp;: &nbsp; Internet–Surfen (''Info–on–demand''), Online–Printmedien,
 
*''Kommunikation''&nbsp;:  &nbsp; Video– und Audiokonferenz, Fax, ISDN, Messaging,
 
*''Unterhaltung''&nbsp;:  &nbsp; Mobile TV, Mobile Radio, Video–on–Demand, Online–Gaming,
 
*''Geschäftlicher Bereich''&nbsp;: &nbsp;  Interaktives Einkaufen, E–Commerce,
 
*''Technischer Bereich''&nbsp;:  &nbsp; Online–Betreuung, Distributionsservice (Sprache und Daten),
 
*''Medizinischer Bereich''&nbsp;:  &nbsp; Telemedizin.
 
  
  
[[File:P_ID1484__Bei_T_4_1_S9_v1.png|Right|frame|Zusammenstellung und Klassifizierung der UMTS–Dienste]]
+
{{GraueBox|TEXT= 
 
$\text{Beispiel 3:}$&nbsp; In der Abbildung sind die UMTS&ndash;Dienste nach verschiedenen Merkmalen  klassifiziert:
 
#nach Datenrate in vertikaler Richtung,
 
#nach Art der Verbindung  (bidirektional, unidirektional, Broadcast) in horizontaler Richtung.
 
  
 +
==Security aspects==
 +
<br>
 +
The security features in UMTS networks are based on the same principles as in GSM.&nbsp; However,&nbsp; some GSM security features have been removed,&nbsp; replaced or expanded.
  
 +
This has made
 +
#the encryption algorithms more robust,
 +
#the authentication algorithms more stringent,&nbsp; and
 +
#the subscriber confidentiality criteria tighter.
  
  
''Anmerkungen:''
+
The main security standards adopted from GSM in UMTS are:
*Die Höhe eines Kästchens gibt (in etwa) den Bereich für die erforderliche Datenrate an.
+
#&nbsp;subscriber authentication,
*Die Breite deutet näherungsweise auf den Datenumfang hin.}}
+
#&nbsp;confidentiality of the subscriber identity,
+
#&nbsp;encryption of the radio interface.
  
==Security aspects==
 
<br>
 
Die Sicherheitsmerkmale in UMTS–Netzen basieren auf den gleichen Prinzipien wie bei GSM. Allerdings wurden einige GSM–Sicherheitsfunktionen entfernt, ersetzt oder ausgebaut. Dadurch wurden
 
*die Verschlüsselungsalgorithmen robuster,
 
*die Authentifizierungsalgorithmen strenger und
 
*die Kriterien zur Vertraulichkeit eines Teilnehmers enger.
 
  
 +
In addition to these, other security measures have been observed in UMTS:
 +
#&nbsp;Mutual authentication to avoid the use of false base stations,
 +
#&nbsp;encryption of the connection between base station and associated control node,
 +
#&nbsp;encryption and authentication of security data during transmission,
 +
#&nbsp;mechanisms for updating the security features.
 +
[[File:EN_Bei_T_4_1_S10_v2.png|right|frame|Compilation of security measures in UMTS]]
  
Die wesentlichen von GSM übernommenen Sicherheitsstandards bei UMTS sind:
 
#&nbsp;Authentifizierung des Teilnehmers,
 
#&nbsp;Vertraulichkeit der Teilnehmeridentität,
 
#&nbsp;Verschlüsselung der Funkschnittstelle.
 
  
  
Zusätzlich zu diesen wurden bei UMTS noch weitere Sicherheitsmaßnahmen beachtet:
+
One can classify the above security measures according to the graph.&nbsp; A distinction is made between security concepts for
#&nbsp;Gegenseitige Authentifizierung, um die Nutzung falscher Basisstationen zu vermeiden,
+
*the&nbsp; '''&raquo;Network Access Security&laquo;'''&nbsp; for each subscriber,
#&nbsp;Verschlüsselung der Verbindung zwischen Basisstation und zugehörigem Kontrollknoten,
 
#&nbsp;Verschlüsselung und Authentifizierung der Sicherheitsdaten bei der Übertragung,
 
#&nbsp;Mechanismen zur Aktualisierung der Sicherheitsmerkmale.
 
  
 +
*the&nbsp; '''&raquo;User Domain Security&nbsp;&laquo;'''&nbsp; &ndash; access to terminal equipment is ensured,
  
Man kann die oben aufgeführten Sicherheitsmaßnahmen entsprechend der Grafik klassifizieren.
+
*the&nbsp; '''&raquo;Network Domain Security&laquo;'''&nbsp; &ndash; a secure exchange of control data between nodes within the network domain is ensured,
  
[[File:P_ID1486__Bei_T_4_1_S10_v1.png|right|frame|Zusammenstellung der Sicherheitsmaßnahmen bei UMTS]]
+
*the&nbsp; '''&raquo;Application Domain Security&laquo;'''&nbsp; &ndash; the secure exchange between applications of the subscriber terminals and the network providers is guaranteed.
Man unterscheidet Sicherheitskonzepte für
 
*den sicheren&nbsp; '''Netzzugang'''&nbsp; (''Network Access Security'')&nbsp; für jeden Teilnehmer,
 
  
*die&nbsp; '''Netzdomäne'''&nbsp; (''Network Domain Security'')&nbsp; – ein sicherer Austausch von Kontrolldaten zwischen den Knoten innerhalb der Netzdomäne wird sichergestellt,
 
  
*die&nbsp; '''Teilnehmerdomäne'''&nbsp; (''User Domain Security'')&nbsp; – der Zugang zu den Endgeräten wird sichergestellt,
+
The UMTS subscriber can see at any time which of these security measures are in operation and which of them are required for specific services.&nbsp; In this context,&nbsp; one speaks of&nbsp; "Visibility and Configurability Security".
*die&nbsp; '''Anwendungsdomäne'''&nbsp; (''Application Domain Security'')&nbsp; – der sichere Austausch zwischen Anwendungen der Teilnehmerendgeräte und der Netzanbieter wird garantiert.
 
<br clear=all>
 
Der UMTS–Teilnehmer kann jederzeit erkennen, welche dieser Sicherheitsmaßnahmen in Betrieb sind und welche davon für bestimmte Dienste benötigt werden. Man spricht in diesem Zusammenhang von ''Sichtbarkeit'' und ''Konfigurierbarkeit'' der Sicherheit.
 
  
 
 
 
 
==Aufgaben zum Kapitel==
+
==Exercises for the chapter==
 
<br>  
 
<br>  
[[Aufgaben:Aufgabe_4.1:_Verschiedene_Duplexverfahren_bei_UMTS|Aufgabe 4.1: Verschiedene Duplexverfahren bei UMTS]]
+
[[Aufgaben:Exercise_4.1:_Different_Duplex_Methods_for_UMTS|Exercise 4.1: Different Duplex Methods for UMTS]]
  
[[Aufgaben:Aufgabe_4.2:_Grundlegendes_zum_UMTS-Funkkanal|Aufgabe 4.2: Grundlegendes zum UMTS-Funkkanal]]
+
[[Aufgaben:Exercise_4.2:_UMTS_Radio_Channel_Basics|Exercise 4.2: UMTS Radio Channel Basics]]
  
  
 
{{Display}}
 
{{Display}}

Latest revision as of 14:00, 13 March 2023

# OVERVIEW OF THE FOURTH MAIN CHAPTER #


$\rm U$niversal  $\rm M$obile  $\rm T$elecommunications  $\rm S$ystem  $\rm (UMTS)$  is a third-generation mobile communications system,  which,  when it was introduced,  was intended to be a forward-looking alternative to the mobile communications systems used until then.  Compared with GSM,  UMTS not only offers higher-quality speech,  but also a variety of enhanced services and functionalities thanks to its faster and packet-switched transmission.

UMTS was standardized in the late 1990s as part of a collaboration between the  "International Telecommunication Union"  $\rm (ITU)$  and the 3GPP Forum  $($"3rd Generation Partnership Project"$)$  and has been commercially available in Europe since 2004.

⇒   In 2011  $($when this chapter was conceived$)$  about 200 million subscribers worldwide were using UMTS or similar third-generation mobile communications systems.

⇒   In 2022  $($when this chapter was revised again as part of the English translation$)$  a global report by the network equipment industry has identified more than hundred operators  that have either completed 3G switch-off alongside 2G switch-off,   are planning to do so or are in the process of doing so,  in order to use the spectrum this frees up for  "LTE",  "5G"  or technology-neutral.

  • 28 operators in 17 countries and territories have now completed 3G switch-off.
  • Six operators in six countries and territories currently have 3G switch-off underway.
  • Another 46 operators in 31 countries have 3G shutdowns planned for the very near future.
  • It is also interesting to note from this report that in some countries the UMTS switch-off is being pushed even harder than that of the 2G standard  "GSM",  which is about ten years older.


⇒   We have chosen to keep this chapter in our  $\rm LNTwww$  despite this negative forecast,  since understanding the underlying CDMA technology also facilitates students' understanding of other communications engineering problems.

This chapter includes in detail:

  1. »UMTS«  as a third-generation mobile communications system,
  2. the  »services and security aspects«  in UMTS,
  3. the  »UMTS network architecture«,
  4. the  »physical, logical and transport channels«  and their interactions,
  5. the  »cellular architecture in UMTS«  and its mechanisms,
  6. the  »speech and channel coding«  used in UMTS,
  7. the  »band spreading and CDMA«  as the basis of UMTS,
  8. the  »radio resource management and power control«  in UMTS networks,
  9. the  »further developments of UMTS«  such as  »HSDPA«  and  »HSUPA«,
  10. an outlook on  »Long Term Evolution«  $\rm (LTE)$,  the buzzword of the fourth generation.


Requirements for third–generation mobile communications systems


The main motivation for the development of  »third-generation mobile communications systems«  was the realization that second-generation systems could not satisfy the bandwidth requirements for the use of multimedia services.

Development of mobile communications systems from 1995 to 2006

The graph shows the development of mobile radio systems since 1995 in terms of performance or data transmission rate as seen in 2007:

  • The specified data rates for HSUPA  $($uplink,  up to  $\text{3 Mbit/s)}$  and HSDPA  $($downlink,  up to  $\text{7 Mbit/s)}$  were realistic for 2006/2007.
  • In contrast,  the specifications stated maximum values for the uplink  $\text{5.8 Mbit/s}$  and for the downlink  $\text{14.4 Mbit/s}$ $($i.e., significantly higher maximum values$)$,  but these will probably not be achievable in practice.
  • The third-generation mobile communications systems were to have greater bandwidth than the  "GSM"  already established at that time and sufficient reserve capacity to ensure high quality of service even in the face of constantly growing demands.
  • In the development of the 3G systems,  the  "International Telecommunication Union"  $\rm (ITU)$  has played an important role.  Among other things,  it created a catalog of requirements that defined their characteristics.


This catalog of requirements includes the following general conditions:

  1. High data rates from  $\text{144 kbit/s}$  $($standard$)$  to  $\text{2 Mbit/s}$  $($in-door$)$,
  2. symmetric and asymmetric data transmission  $($IP services$)$,
  3. circuit-switched and packet-switched transmission,
  4. high speech quality and high spectral efficiency,
  5. seamless transition to and from second-generation systems,
  6. global reachability and distribution,
  7. applications independent of the network used $($virtual home environment$)$.


The IMT–2000 standard


In 1992,  the  "International Telecommuncation Union"  $\rm (ITU)$  launched the  $\text{IMT-2000}$  $($"International Mobile Telecommunications at  2000 MHz"$)$  standard to enable the above requirements.  This comprises a number of different third-generation mobile communications systems that have been converged during the standardization process to enable the development of common terminals for all these standards.

In order to take into account nationally different preliminary work and to allow network operators to continue using existing network architectures to some extent, 

The "IMT family" – an overview

IMT–2000 includes several individual standards.  These can be roughly divided into four categories:

  • $\rm W\hspace{-0.12cm}-\hspace{-0.08cm}CDMA$:   This includes the FDD component of the European UMTS standard as well as the American  "cdma2000"  system.
  • $\rm TD\hspace{-0.08cm}-\hspace{-0.08cm}CDMA$:   This group includes the TDD component of UMTS as well as the Chinese  "TD-SCDMA",  which is now integrated into the  "UMTS–TDD"  standard.
  • $\rm TDMA$:   A further development of the GSM off-shoot  "EDGE"  and its American counterpart  "UWC-136",  also known as  "DS-AMPS".
  • $\rm FD\hspace{-0.08cm}-\hspace{-0.08cm}CDMA$:   The further development of the European cordless telephony standard  $\rm DECT$  $($"Digital Enhanced Cordless Telecommunication"$)$.


In the following,   we focus on the European-developed system  $\rm UMTS$  $($"Universal Mobile Telecommunications System"$)$,   which supports the first two standards  "$\rm W\hspace{-0.12cm}-\hspace{-0.08cm}CDMA$"  and  "$\rm TD\hspace{-0.08cm}-\hspace{-0.08cm}CDMA$"  of the  IMT–2000  system family.


Historical development of UMTS


The following is some data on the historical development of UMTS and the techniques used.  More information can be found,  for example,  at this "internet link".

  • 1940-1950   First military applications of signal spreading techniques.
  • 1949   First outlines of the CDMA process by C. E. Shannon and J. R. Pierce.
  • 1970   Various CDMA developments for military systems, e.g. GPS.
  • 1989-1992   Basic research on the characteristics of future mobile radio systems within the EU program RACE-1  $($Research,  Analysis,  Communication,  Evaluation$)$.
  • 1992   First consideration of the IMT-2000 standard by the ITU.
  • 1992-1995   EU program RACE-2 focusing on "development of system concepts" - based on the results of RACE-1.
  • 1996   Foundation of the UMTS Forum in Zurich - renaming of the planned European standard  "W-CDMA"  to  "UMTS".
  • 1998   Adoption of the two modes  "W-CDMA"  and  "TD-CDMA" ' into the UMTS standard at the ETSI-SMG meeting in Paris.
  • 1998   Establishment of the  "3gpp forum"  $($"3rd Generation Partnership Project"$)$  by the ETSI-SMG,  T1P1,  ARIB TTC  and  TTA committees.
  • 1999   Adoption of the UMTS-R99 standard $($Release 1999$)$  by ETSI.  This is considered the basis for the first available UMTS terminals.
  • 2001  Adoption of Release 4 as a further development of UMTS-R99:  "Quality of Service"  $\rm (QoS)$  is now supported at the radio interface and in the fixed network.
  • 2001   First commercial UMTS network of the Norwegian company  "TELENOR".
  • 2002   Adoption of UMTS Release 5:   Architecture based on the GSM fixed network is replaced by a fully IP-based fixed network.
  • 2002   First UMTS speech and data link from  "Nortel Networks"  and  "Qualcomm".  These companies are considered pioneers in the implementation of UMTS.
  • 2004   Adoption of UMTS Release 6,  a standard that provides improved QoS for the user and more effective resource management for the provider.


With UMTS, too,  more than a decade has passed between the first conceptual considerations and the final introduction.

This was similar to the introduction of other communications systems,  such as

  • "ISDN"  $($"Integrated Services Digital Network"$)$,
  • "DSL"  $($"'Digital Subscriber Line"$)$,
  • "GSM"  $($"Global System for Mobile Communications"$)$.


Frequency allocation for UMTS


The  International Telecommunication Union  $\rm (ITU)$  is responsible for allocating bandwidths and frequency bands for communications systems.  In the case of UMTS in particular,  however,  there are discrepancies between the European and ITU frequency allocations,  as some frequency bands were already occupied by other mobile communications systems in some countries. 

UMTS frequency spectra

The graph shows the European  $($bottom$)$  and the ITU frequency assignments  $($top$)$.  Meaning:

$\rm GSM \ 1800$:
Frequency band for the downlink of GSM 1800,

$\rm SAT$:
Satellite-based systems   $($each  $\text{30 MHz}$  for uplink and downlink$)$,

$\rm DECT$:
Digital Enhanced Cordless Telecommunications,

$\rm UTRA\:FDD$,   for short:   $\rm FDD$:
UMTS Terrestrial Radio Access  –  Frequency Division Duplex,

$\rm UTRA\:TDD$,   for short:   $\rm TDD$:
UMTS Terrestrial Radio Access  –  Time Division Duplex.


Note:

⇒   $\rm FDD$  consists of twelve paired uplink and downlink frequency bands of  $\text{5 MHz}$  bandwidth each. The frequency bands are located in Europe between

  •   $\text{1920 MHz}$  and  $\text{1980 MHz}$  in the uplink,
  •   $\text{2110 MHz}$  and  $\text{2170 MHz}$  in the downlink.


⇒   $\rm TDD$  consists of five frequency bands of  $\text{5 MHz}$  bandwidth each,  in which both uplink and downlink data are to be transmitted using time division multiplexing.

  • The TDD band lies between  $\text{1900 MHz}$  and  $\text{1920 MHz}$  $($four channels$)$  and between  $\text{2020 MHz}$  and  $\text{2025 MHz}$  $($one channel$)$.
  • The band between  $\text{2010 MHz}$  and  $\text{2020 MHz}$  has not been licensed in 2007.


Full duplex


In order to separate the two transmission directions uplink and downlink,  two different operating modes are supported in UMTS.  A distinction is made between:

»UMTS Terrestrial Radio Access Frequency Division Duplex«  $\rm (UTRA\hspace{-0.08cm}-\hspace{-0.08cm}FDD)$,
»UMTS Terrestrial Radio Access Time Division Duplex«  $\rm (UTRA\hspace{-0.08cm}-\hspace{-0.08cm}TDD)$,

  • The main difference between these two modes can be seen in the physical layer of the protocol stack.
  • The two methods differ in both their duplex and multiple access methods.


UTRA-FDD mode in UMTS

In the   $\rm UTRA\hspace{-0.08cm}-\hspace{-0.08cm}FDD$  mode,  as shown in the graph on the right:

  1. Uplink and downlink data are transmitted simultaneously on different but corresponding paired  $\text{5 MHz}$  frequency blocks.
  2. Data from different subscribers are transmitted and received on the same frequency band.
  3. The use of different CDMA spreading codes enables the separation of the respective subscriber data.
  4. The  TDMA method  is also used to realize periodic functions such as power control.
  5. The  FDMA method  can be used in addition to CDMA and TDMA if the network operator has more than one frequency channel.


FDD mode is used only in Europe and mostly only for symmetrical services whose bandwidth requirements in the uplink and downlink are approximately the same.  This is the case for speech communications or video telephony,  for example.


UTRA TDD mode in UMTS

In the   $\rm UTRA\hspace{-0.08cm}-\hspace{-0.08cm}TDD$  mode,  uplink and downlink data are transmitted in the same frequency band.  In this case,  uplink and downlink are separated in time,  as shown in the following diagram. Furthermore:

  1. The  "switching point"  can be flexibly selected depending on the data volume ratio between uplink and downlink.
  2. In TDD mode,  the subscribers are identified both by the spreading code  $($as in FDD$)$  and by the time slot.
  3. If the network operator has several frequency channels,  FDMA can be used in addition to CDMA and TDMA as with FDD.


TDD mode was 2007 not used in Europe and,  once introduced,  will mainly be used for asymmetric services  where the data volumes of downlink and uplink differ significantly.

Properties of the UMTS radio channel


In the UMTS radio channel,  in addition to interference from other subscribers and noise,  a number of unpredictable,  interfering and distorting effects occur,  which also change over time.

Example for a mobile radio scenario

⇒   Due to reflections as well as scattering and diffraction from objects,  the transmitted signal experiences  »multipath propagation«.

  • The signal reaches the receiver not only via the direct path,  but via several paths with different propagation times and different attenuation.
  • The multipath scattering is influenced by the environment,  but additionally also by a possible movement of the user,  as indicated in the graph by the movement speed  $v$.


⇒   The  path loss goes back to propagation properties of electromagnetic waves – see page  "common path loss model"  in the book  "Mobile Communication".  For the study of this attenuation phenomenon,  we assume a simplified path loss model.  This states:

  • The received power of a radio signal decreases with distance  $d$  by  $d^{-γ}$,  where  $γ$   is a medium-dependent constant of the radio propagation wave.
  • Accounting for constructive or destructive ground reflections,  the constant  $γ$   below the  "break point"  $d_0$  takes values between  $2$  and  $3$.
  • Above this characteristic point,  the reflection effects increase and the propagation constant  $γ$   grows to values between  $3.5$  and  $4$.


$\text{Example 1:}$  Shown on the right is the path loss  $($in dB$)$  as a function of the distance  $d$  $($in meter$)$.

Path loss  $($attenuation$)$  as a function of the distance

In this example,

  • the constant  $α_0 = 10^{-5}$  is set   ⇒   $10 \cdot \lg \ α_0 = 50 \ \rm dB$,
  • the break point is at  $d_0 = \ \rm 100 \ m$.





One can see from the graph:

  1. In the left-hand range  $(d \ll d_0)$  holds  $γ \approx 2$

  2. For  $d \gg d_0$  on the other hand:  $γ \approx 4$.

  3. In the region around  $d = d_0$: 
    The propagation constant increases continuously from  $γ = 2$   to  $γ = 4$.


Frequency–selective and time–selective fading


An essential property of the mobile radio channel is the so-called   »fading«.  This is caused by time-varying shadowing and by possible movements of the mobile subscriber.  In the book  "Mobile Communications"  this type of signal degradation is discussed in detail.

Here follows only a brief summary.  One distinguishes on the one hand:

  • »Short term fading«  or  "fast fading"    ⇒   short term drops in the received power   $($mostly in the microseconds range$)$.
  • »Long term fading«  or  "slow fading"   ⇒   only slow changes  $($mostly in the seconds range$)$.
Fast fading mainly affects systems with large symbol durations,  i.e.  small bandwidths.  However,  since the bandwidth of UMTS is much larger than that of GSM,  this system is less susceptible to fast fading.

Furthermore,  fading can also be classified as follows:

  • »Frequency-selective fading«  is caused by multipath propagation over paths with different delay times.
        As a result of this fading,  different frequency components are attenuated differently by the power transfer function  $|H_{\rm K}(f)|^2$  of the channel.
  • »Time-selective fading«  occurs due to a relative motion between transmitter and receiver.
        This causes frequency shifts depending on the direction of movement  $($towards or away from the transmitter$)$  which are physically described by the  "Doppler effect".
The fading characteristics  "frequency selective"  and  "time selective"  shall now be explained in more detail,  in particular it will be explained under which conditions which of these fading types are to be expected.  At this point we also refer to two e-learning tools:
  1. HTML5/JavaScript applet  "The Doppler effect",
  2. German language SWF applet  "Multipath propagation and frequency selectivity".

$\text{Characteristics of frequency-selective fading:}$ 

  • Receiving different scattering components with different delay times results in a  »delay spread«  $T_{\rm V}$, defined as the difference between maximum and minimum delay times  $($ German:  "Verzögerungszeiten   ⇒   subscript "V"$)$.  The inverse of this gives approximately the  »coherence bandwidth«  $B_{\rm K}$.
  • It is called  "frequency-selective fading"  if the coherence bandwidth  $B_{\rm K}$  is much smaller than the signal bandwidth  $B_{\rm S}$.  As a result,  different frequency components are attenuated differently by the channel,  resulting in linear distortions.


$\text{Characteristics of time-selective fading:}$ 

  • In  "time-selective fading",  a so-called  »Doppler spread«  $B_{\rm D}$» occurs,  which is defined as the difference between maximum and minimum Doppler frequencies.
  • The reciprocal of which is called the  "correlation time"  $T_{\rm D} = {1}/{B_{\rm D} }$.  In some literatures,  this quantity is also referred to as  "coherence time".  In UMTS,  "time-selective fading"  occurs whenever the correlation time  $T_{\rm D}$  is much smaller than the chip duration  $T_{\rm C}$.


$\text{Example 2:}$  The left graph illustrates the difference between frequency-selective and non-frequency-selective fading:

The red curves illustrate frequency-selective and time-selective fading
  1. Shown in this graph is the logarithm power transfer function  $\vert H_{\rm K}(f,\ t)\vert ^2$  of the channel at a fixed time  $t$.
  2. While non-frequency-selective fading is plotted in blue with  $-5 \ \rm dB$ , the red curve shows an example of frequency-selective fading.
  3. Different frequency components are thereby attenuated differently.


The right graph shows schematically  "time-selective fading":

  1. Here,  the power transfer function  $\vert H_{\rm K}(f,\ t) \vert ^2$  of the channel for a fixed frequency  $f$ is plotted.
  2. The blue curve is valid for non-time-selective fading:  At any time the signal is attenuated by  $5 \rm dB$ .


UMTS services


One of the goals of the introduction of UMTS is to expand and diversify the mobile communications services offered.  A UMTS capable terminal must support a number of more complex multimedia applications and functions in addition to the classic services  $($speech transmission,  messaging, ...$)$.

These services can be divided into six main categories,  depending on the application:

  1. Information :   Internet surfing  $($info-on-demand$)$,  online print media,
  2. Communication:   Video and audio conferencing,  fax,  ISDN,  messaging,
  3. Entertainment:   Mobile TV,  mobile radio,  video-on-demand,  online gaming,
  4. Business:   Interactive shopping,  e-commerce,
  5. Technical area:   Online support,  distribution service  $($speech and data$)$,
  6. Medical area:   Telemedicine.



Security aspects


The security features in UMTS networks are based on the same principles as in GSM.  However,  some GSM security features have been removed,  replaced or expanded.

This has made

  1. the encryption algorithms more robust,
  2. the authentication algorithms more stringent,  and
  3. the subscriber confidentiality criteria tighter.


The main security standards adopted from GSM in UMTS are:

  1.  subscriber authentication,
  2.  confidentiality of the subscriber identity,
  3.  encryption of the radio interface.


In addition to these, other security measures have been observed in UMTS:

  1.  Mutual authentication to avoid the use of false base stations,
  2.  encryption of the connection between base station and associated control node,
  3.  encryption and authentication of security data during transmission,
  4.  mechanisms for updating the security features.
Compilation of security measures in UMTS


One can classify the above security measures according to the graph.  A distinction is made between security concepts for

  • the  »Network Access Security«  for each subscriber,
  • the  »User Domain Security «  – access to terminal equipment is ensured,
  • the  »Network Domain Security«  – a secure exchange of control data between nodes within the network domain is ensured,
  • the  »Application Domain Security«  – the secure exchange between applications of the subscriber terminals and the network providers is guaranteed.


The UMTS subscriber can see at any time which of these security measures are in operation and which of them are required for specific services.  In this context,  one speaks of  "Visibility and Configurability Security".


Exercises for the chapter


Exercise 4.1: Different Duplex Methods for UMTS

Exercise 4.2: UMTS Radio Channel Basics