Difference between revisions of "Aufgaben:Exercise 1.1: Multiplexing in the GSM System"

Latest revision as of 17:37, 23 January 2023

Multiplexing in the GSM system

The "Global System for Mobile Communication" $\rm (GSM)$ standard, which has been established in Europe since 1992, uses both frequency division and time division multiplexing to enable several users to communicate in one cell.

Some characteristics of the system are given below in a somewhat simplified form. A more detailed description can be found in the chapter General Description of GSM in the book "Examples of Communication Systems".

The frequency band of the uplink (connection from the mobile to the base station) is between $\text{890 MHz}$ and $\text{915 MHz}$ .
Taking into account the guard bands $($ each $\text{100 kHz)}$ at both ends, a total uplink bandwidth of $\text{24.8 MHz}$ is available.
This band is used by $K_{\rm F}$ subchannels ("Radio Frequency Channels"), which are adjacent in frequency with a respective spacing of $\text{200 kHz}$ . The numbering is done with the running variable $k_{\rm F}$ , starting with $k_{\rm F} = 1$ .
The frequency range for the downlink (connection from the base station to the mobile) is $\text{45 MHz}$ above the uplink and is structured in exactly the same way as the uplink.
Each of these FDMA subchannels is used simultaneously by $K_{\rm T}$ users via TDMA ("Time Division Multiple Access").
A time slot of duration $T ≈ 577 \ \rm µ s$ is available to each user at intervals of $\text{4.62 ms}$ .
During this time, the (approximate) $156$ bits describing the speech signal must be transmitted, taking into account data reduction and channel coding.

Hints:

This exercise belongs to the chapter Objectives of Modulation and Demodulation.
Particular reference is made to the pages
- Channel bundling – Frequency Division Multiplexing,
- Time Division Multiplex methods.

Questions

$K_{\rm F} \ = \$

$f_{\rm M} \ = \$

$\ \rm MHz$

$k_{\rm F} \ = \$

$K_{\rm T} \ = \$

$K \ = \$

$R_{\rm gross} \ = \$

$\ \rm kbit/s$

Solution

(1) From a total bandwidth of

$\text{24.8 MHz}$ and a channel spacing of

$\text{200 kHz}$ follows:

$K_{\rm F}\hspace{0.15cm}\underline{ = 124}.$

(2) The center frequency of the first channel is $\text{890.2 MHz}$ . The "RFCH 100" channel is $\text{ 99 · 200 kHz = 19.8 MHz}$ higher:

$f_{\rm M}= 890.2 \ \rm MHz + 19.8 \ \rm MHz\hspace{0.15cm}\underline{ = 910 \ \rm MHz}.$

(3) To apply the logic from subtask (2), we transfer the task into the uplink:

The same channel with the identifier $k_{\rm F}$ , which uses the frequency $\text{940 MHz}$ in the downlink, is located at $\text{895 MHz}$ .
Thus:

$k_{\rm F} = 1 + \frac {895 \,\,{\rm MHz } - 890.2 \,\,{\rm MHz } }{0.2 \,\,{\rm MHz }} \hspace{0.15cm}\underline {= 25}.$

(4) In a TDMA frame of duration $\text{4.62}$ millisekconds, $K_{\rm T}\hspace{0.15cm}\underline{ = 8}$ time slots with a respective duration of $T = 577 \ \rm µ s$ can be accommodated.

Note: For GSM,

$K_{\rm T} = 8$ is actually used.

(5) Using the results of subtasks (1) und (4) we obtain:

$K = K_{\rm F} \cdot K_{\rm T} = 124 \cdot 8 \hspace{0.15cm}\underline {= 992}$

(6) Over the course of timespan $T = 577 \ \rm µs$ ⇒ $156$ bits must be transmitted.

Thus, each bit has the time $T_{\rm B} = 3.699 \ \rm µ s$ available.
This results in the (gross) bit rate:

$R_{\rm gross} = \frac {1 }{T_{\rm B}}\hspace{0.15cm}\underline {\approx 270 \,\,{\rm kbit/s }}.$

This gross bit rate includes the training sequence for channel estimation, the redundancy for channel coding in addition to the data representing the speech signal.
The net bit rate for the GSM system is only about $\text{13 kbit/s}$ for each of the eight users.

@@ Line 1: / Line 1: @@
-oma
-{{quiz-Header|Buchseite=Modulationsverfahren/Zielsetzung von Modulation und Demodulation
+{{quiz-Header|Buchseite=Modulation_Methods/Objectives_of_Modulation_and_Demodulation
 }}
-[[File:P_ID938__Mod_A_1_1.png|right|]]
+[[File:EN_Mod_A_1_1.png|right|frame|Multiplexing in the GSM system]]
-Der seit 1992 in Europa etablierte Mobilfunkstandard $\text{GSM}$ (''Global System for Mobile''
+The&nbsp; "Global System for Mobile Communication"&nbsp;  $\rm (GSM)$ &nbsp;  standard,&nbsp; which has been established in Europe since 1992,&nbsp; uses both frequency division and time division multiplexing to enable several users to communicate in one cell.
-''Communication'') nutzt sowohl Frequenz– als auch Zeitmultiplex, um mehreren Teilnehmern die Kommunikation in einer Zelle zu ermöglichen.
+Some characteristics of the system are given below in a somewhat simplified form.&nbsp;  A more detailed description can be found in the chapter &nbsp;[[Examples_of_Communication_Systems/Allgemeine_Beschreibung_von_GSM|General Description of GSM]]&nbsp; in the book&nbsp; "Examples of Communication Systems".
+*The frequency band of the uplink&nbsp; (connection from the mobile to the base station)&nbsp; is between&nbsp;  $\text{890 MHz}$ &nbsp; and&nbsp;  $\text{915 MHz}$ .&nbsp;
+*Taking into account the guard bands&nbsp;  $($ each&nbsp;   $\text{100 kHz)}$ &nbsp; at both ends, a total uplink bandwidth of &nbsp; $\text{24.8 MHz}$&nbsp; is available.
+*This band is used by&nbsp; $K_{\rm F}$&nbsp; subchannels ("Radio Frequency Channels"),&nbsp; which are adjacent in frequency with a respective spacing of &nbsp;  $\text{200 kHz}$ .&nbsp;  The numbering is done with the running variable &nbsp; $k_{\rm F}$ , starting with &nbsp; $k_{\rm F} = 1$ .
+* The frequency range for the downlink&nbsp; (connection from the base station to the mobile)&nbsp; is&nbsp;  $\text{45 MHz}$ &nbsp; above the uplink and is structured in exactly the same way as the uplink.
+*Each of these FDMA subchannels is used simultaneously by &nbsp; $K_{\rm T}$ &nbsp; users via TDMA&nbsp; ("Time Division Multiple Access").
+*A time slot of duration &nbsp;  $T ≈ 577 \ \rm &micro; s$ &nbsp; is available to each user at intervals of &nbsp; $\text{4.62 ms}$ .
+* During this time,&nbsp; the (approximate) &nbsp;  $156$ &nbsp; bits describing the speech signal must be transmitted,&nbsp; taking  into account data reduction and channel coding.
+Hints:
+*This exercise belongs to the chapter&nbsp; [[Modulation_Methods/Objectives_of_Modulation_and_Demodulation|Objectives of Modulation and Demodulation]].
+*Particular reference is made to the pages
+**[[Modulation_Methods/Objectives_of_Modulation_and_Demodulation#Channel_bundling_.E2.80.93_Frequency_Division_Multiplexing|Channel bundling  &ndash; Frequency Division Multiplexing]],&nbsp;
+**[[Modulation_Methods/Objectives_of_Modulation_and_Demodulation#Time_Division_Multiplex_methods|Time Division Multiplex methods]].
-Nachfolgend sind einige Charakteristika des Systems in etwas vereinfachter Form angegeben. Eine exaktere Beschreibung finden Sie im [http://en.lntwww.de/Beispiele_von_Nachrichtensystemen/Allgemeine_Beschreibung_von_GSM Kapitel 3] des letzten LNTwww–Fachbuches „Beispiele von Nachrichtensystemen”.
-:* Das Frequenzband des Uplinks (die Verbindung von der Mobil– zur Basisstation) liegt zwischen 890 und 915 MHz. Unter Berücksichtigung der Guard–Bänder (von je 100 kHz) an den beiden Enden steht somit für den Uplink eine Gesamtbandbreite von 24.8 MHz zur Verfügung.
+===Questions===
-:*Dieses Band wird von insgesamt  $K_F$  Teilkanälen (''Radio Frequency Channels'') genutzt, die mit einem jeweiligen Abstand von 200 kHz frequenzmäßig nebeneinander liegen. Die Numerierung geschieht mit der Laufvariablen  $k_F$ , beginnend mit 1.
-:* Der Frequenzbereich für den Downlink (die Verbindung von der Basis– zur Mobilstation) liegt um 45 MHz oberhalb des Uplinks und ist in genau gleicher Weise wie dieser aufgebaut.
-:*Jeder dieser  $\text{FDMA}$ –Teilkanäle wird gleichzeitig von  $K_T$  Teilnehmern per  $\text{TDMA}$  (''Time Division Multiple Access'') genutzt.
-:*Jedem Teilnehmer steht im Abstand von 4.62 Millisekunden ein Zeitschlitz der Dauer T ≈ 577 μs zur Verfügung. Während dieser Zeit müssen die (näherungsweise) 156 Bit übertragen werden, die das Sprachsignal unter Berücksichtigung von Datenreduktion und Kanalcodierung beschreiben.
-'''Hinweis:''' Diese Aufgabe bezieht sich auf die theoretischen Grundlagen von [http://en.lntwww.de/Modulationsverfahren/Zielsetzung_von_Modulation_und_Demodulation Kapitel 1.1].
-===Fragebogen===
 <quiz display=simple>
-{Wieviele Teilkanäle entstehen durch Frequenzmultiplex?
+{How many subchannels result from&nbsp; "Frequency Division Multiplexing"?
 |type="{}"}
-$K_F$ = { 124 1% }
+$K_{\rm F} \ = \ $  { 124 }
-{Welche Mittenfrequenz $f_M$ hat der Radio ''Frequency Channel'' im Uplink mit der laufenden Nummer $k_F$ = 100?
+{What is the center frequency &nbsp;$f_{\rm M}$&nbsp;of the&nbsp; "Radio Frequency Channel"&nbsp; in the uplink with number &nbsp;$k_{\rm F} = 100$?
 |type="{}"}
-$f_M (k_F = 100)$= { 910 1% }  $MHz$
+$f_{\rm M} \ = \  ${ 910 1% }$ \ \rm MHz$
-{Welcher Downlink–Kanal (Nummer $k_F$) benutzt die Frequenz 940 $MHz$?
+{Which downlink subchannel &nbsp; $($number &nbsp;$k_{\rm F}) $&nbsp; uses the frequency&nbsp;$ \text{940 MHz}$?
 |type="{}"}
-$K_F$= { 25 1% }
+$k_{\rm F} \ = \ $ { 25 }
-{Wieviele Teilkanäle entstehen bei $\text{GSM}$ durch Zeitmultiplex?
+{How many subchannels result in GSM through&nbsp; "Time Division Multiplexing"?
 |type="{}"}
-$K_T$={ 8 1% }
+$K_{\rm T} \ = \ $ { 8 }
+{How many GSM users can be simultaneously active in one cell?
+|type="{}"}
+ $K \ = \$  { 992 1% }
+{How big is the gross bit rate for GSM?
+|type="{}"}
+ $R_{\rm gross} \ = \$  { 270 3% }  $\ \rm kbit/s$
 </quiz>
-===Musterlösung===
+===Solution===
 {{ML-Kopf}}
-'''1.'''
+'''(1)'''&nbsp; From a total bandwidth of&nbsp;  $\text{24.8 MHz}$ &nbsp; and a channel spacing of&nbsp;  $\text{200 kHz}$ &nbsp; follows:
-'''2.'''
+: $K_{\rm F}\hspace{0.15cm}\underline{ = 124}.$
-'''3.'''
-'''4.'''
-'''5.'''
+'''(2)'''&nbsp; The center frequency of the first channel is&nbsp;  $\text{890.2 MHz}$ .&nbsp; The "RFCH 100" channel is&nbsp;  $\text{ 99 · 200 kHz = 19.8 MHz}$ &nbsp; higher:
-'''6.'''
+: $f_{\rm M}= 890.2 \ \rm  MHz + 19.8 \ \rm  MHz\hspace{0.15cm}\underline{ = 910 \ \rm  MHz}.$
-'''7.'''
+'''(3)'''&nbsp; To apply the logic from subtask&nbsp; '''(2)''',&nbsp; we transfer the task into the uplink:
+*The same channel with the identifier&nbsp;  $k_{\rm F}$ ,&nbsp; which uses the frequency&nbsp;  $\text{940 MHz}$ &nbsp; in the downlink,&nbsp; is located at&nbsp; &nbsp;  $\text{895 MHz}$ .&nbsp;
+*Thus:
+: $k_{\rm F} = 1 + \frac {895 \,\,{\rm MHz } - 890.2 \,\,{\rm MHz } }{0.2 \,\,{\rm MHz }} \hspace{0.15cm}\underline {= 25}.$
+'''(4)'''&nbsp; In a TDMA frame of duration&nbsp; $\text{4.62} $&nbsp; millisekconds,&nbsp;$ K_{\rm T}\hspace{0.15cm}\underline{  = 8} $&nbsp; time slots with a respective duration of &nbsp;$ T = 577 \ \rm &micro; s$&nbsp; can be accommodated.&nbsp;
+:''Note:''&nbsp; For GSM, &nbsp;  $K_{\rm T} = 8$ &nbsp; is actually used.
+'''(5)'''&nbsp; Using the results of subtasks&nbsp; '''(1)'''&nbsp; und&nbsp; '''(4)'''&nbsp; we obtain:
+: $K = K_{\rm F} \cdot K_{\rm T} = 124 \cdot 8 \hspace{0.15cm}\underline {= 992}$
+'''(6)'''&nbsp; Over the course of timespan&nbsp;  $T = 577 \ \rm &micro;s$ &nbsp; &rArr; &nbsp;  $156$ &nbsp; bits must be transmitted.
+*Thus,&nbsp; each bit has the time&nbsp;  $T_{\rm B} = 3.699 \ \rm &micro; s$ &nbsp; available.
+*This results in the (gross) bit rate:
+: $R_{\rm gross} = \frac {1 }{T_{\rm B}}\hspace{0.15cm}\underline {\approx 270 \,\,{\rm kbit/s }}.$
+*This gross bit rate includes the training sequence for channel estimation, the redundancy for channel coding in addition to the data representing the speech signal.
+*The net bit rate for the GSM system is only about  $\text{13 kbit/s}$  for each of the eight users.
 {{ML-Fuß}}
-[[Category:Aufgaben zu Modulationsverfahren |^1.1 Zielsetzung von Modulation und Demodulation^]]
+[[Category:Modulation Methods: Exercises |^1.1 Why do you need Modulation?^]]