Difference between revisions of "Aufgaben:Exercise 4.1: General Questions about LTE"

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{{quiz-Header|Buchseite=Mobile Kommunikation/Allgemeines zum Mobilfunkstandard LTE
+
{{quiz-Header|Buchseite=Mobile_Communications/General_Information_on_the_LTE_Mobile_Communications_Standard
 
}}
 
}}
  
[[File:P_ID2264__MOB_A4_1_v1.png|right|frame|Einige Begriffe zu „LTE”]]
+
[[File:P_ID2264__MOB_A4_1_v1.png|right|frame|Some terms concerning  $\rm LTE$]]
Die Mobilfunksysteme sind seit 2011 nun schon in der vierten Generation angekommen, ohne gravierende Verzögerungen, wie es bei der zweiten Mobilfunkgeneration (GSM) und noch mehr bei der dritten Generation (UMTS) der Fall war. Momentan (2017) ist „5G” das alles dominierende Schlagwort. Über den Zeitpunkt der Einführung erlaubt sich der Autor allerdings keine präziseren Aussagen als „sehr bald” oder „so bald als möglich”. Genauere Informationen finden Sie  [https://de.wikipedia.org/wiki/5G hier].
+
Since 2011, mobile communications systems have already reached the fourth generation, without serious delays, as was the case with the second generation of mobile communications  $\rm (GSM)$  and even more so with the third generation  $\rm (UMTS)$. 
  
Die Entwicklung von neuen „Releases” wird vom 3GPP stetig vorangetrieben. Auch in der Zukunft wird dieses internationale Konsortium, dem weltweit alle großen Mobilfunkbetreiber und –hersteller angehören, weiterhin eine herausragende Rolle für die Mobilkommunikation spielen.
+
The development of new "releases" is constantly being driven forward by  [[Mobile_Communications/General_Information_on_the_LTE_Mobile_Communications_Standard#3GPP_-_Third_Generation_Partnership_Project  |$\text{3GPP}$]].  This international consortium, which includes all major mobile operators and manufacturers worldwide, will continue to play a prominent role in mobile communications in the future.
  
Besonders für dünn besiedelte ländliche Gebiete ohne ausreichenden DSL–Breitbandanschluss wird LTE bereits seit 2011 kommerziell angeboten. Nach und nach erreicht dieser 4G–Mobilfunkstandard eine immer größere Verbreitung.
+
LTE has been offered commercially since 2011, especially for sparsely populated rural areas without sufficient DSL broadband connections.  This 4G mobile communications standard is gradually becoming more widespread.
  
 +
Currently (2017)  $\rm 5G$  is the all-dominant buzzword.  However, the author does not allow himself any more precise statements about the time of introduction than "very soon" or "as soon as possible".  More detailed information can be found  [https://en.wikipedia.org/wiki/5G here].
  
 +
Meanwhile (2021), we can say:  It was 2019, almost simultaneously in Korea and the US.
  
  
  
  
''Hinweise:''
+
 
 +
 
 +
''Notes:''
 
   
 
   
*Die Aufgabe gehört zum Kapitel  [[Mobile_Kommunikation/Allgemeines_zum_Mobilfunkstandard_LTE|Allgemeines zum Mobilfunkstandard LTE]].  
+
*This task belongs to the chapter  [[Mobile_Communications/General_Information_on_the_LTE_Mobile_Communications_Standard|General Information on the LTE Mobile Communications Standard]].  
*In der Grafik sind einige LTE–relevante Begriffe angegeben. Einen direkten Bezug zur Aufgabe gibt es hierbei aber nicht.
+
*The chart shows some LTE relevant terms.  However, there is no direct reference to the task.
  
  
===Fragebogen===
+
===Questionnaire===
  
 
<quiz display=simple>
 
<quiz display=simple>
  
{Welche wichtigen Neuerungen wurden vom 3GPP im Release 8 beschrieben?
+
{Which important innovations were described by 3GPP in the Release 8?
 
|type="[]"}
 
|type="[]"}
+ Eine rein paketorientierte Übertragung,
+
+ A purely packet-oriented transmission,
+ eine hohe spektrale Effizienz,
+
+ a high spectral efficiency,
+ Frequenz– bzw. Bandbreitenflexibilität,
+
+ frequency or bandwidth flexibility,
- ein niedriger Energieverbrauch an den Basisstationen.
+
- low energy consumption at the base stations.
  
{Wozu dient die Duplexlücke des LTE–Frequenzbands um&nbsp; $800 \ \rm MHz$?
+
{What is the&nbsp; "duplex gap"&nbsp; of the LTE frequency band around&nbsp; $800 \ \rm MHz$&nbsp; for?
 
|type="[]"}
 
|type="[]"}
- Zur Realisierung des&nbsp; ''Cyclic Prefix'',
+
- For the realization of the&nbsp; "Cyclic Prefix",
+ zur Vermeidung von Störungen zwischen Uplink und Downlink,
+
+ to avoid interference between uplink and downlink,
- zur Vermeidung von Überlagerungen zwischen einzelnen Providern.
+
- to avoid overlapping between individual providers.
+ Man nutzt die Duplexlücke auch zum Betrieb von Funkmikrofonen.
+
+ The duplex gap is also used to operate wireless microphones.
  
{Welche Verfahren und Techniken verwendet LTE <u>hauptsächlich</u>?
+
{What methods and techniques does LTE <u>mainly</u> use?
 
|type="[]"}
 
|type="[]"}
 
+ OFDMA,
 
+ OFDMA,
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- CDMA.
 
- CDMA.
  
{Wie unterscheiden sich die Frequenzbänder um&nbsp; $800 \ \rm MHz$&nbsp; bzw. um&nbsp; $2.6 \ \rm GHz$?
+
{How do the frequency bands by&nbsp; $800 \ \rm MHz$&nbsp; and by&nbsp; $2.6 \ \rm GHz$&nbsp; differ?
 
|type="[]"}
 
|type="[]"}
+ Durch unterschiedliche Preise bei der Versteigerung.
+
+ By different prices at the auction.
+ Im Frequenzband um&nbsp; $800 \ \rm MHz$&nbsp; gibt es nur gepaarte Frequenzen.
+
+ In the frequency band around&nbsp; $800 \ \rm MHz$&nbsp; there are only paired frequencies.
- Das Frequenzband um&nbsp; $2.6 \ \rm GHz$&nbsp; kann nur für FDD genutzt werden.
+
- The frequency band around&nbsp; $2.6 \ \rm GHz$&nbsp; can only be used for FDD.
+ Die Einsatzgebiete unterscheiden sich grundlegend.
+
+ The areas of application differ fundamentally.
 +
 
  
 
</quiz>
 
</quiz>
  
===Musterlösung===
+
===Solution===
 
{{ML-Kopf}}
 
{{ML-Kopf}}
  
'''(1)'''&nbsp; Richtig sind die <u>Antworten 1 bis 3</u>, die auch für die wichtigsten Verbesserungen durch LTE stehen:  
+
'''(1)'''&nbsp; Correct are the <u>answers 1 to 3</u>, which also stand for the most important improvements through LTE:  
*Ein niedriger Energieverbrauch an den Basisstationen ist ausdrücklich falsch, denn es geht um einen möglichst niedrigen Energieverbrauch bei den Endgeräten, wofür sogar ein erhöhter Energieverbrauch an den Basisstationen in Kauf genommen wird.
+
*Low power consumption at base stations is explicitly wrong, because the aim is to keep power consumption at the terminals as low as possible, for which even increased power consumption at base stations is accepted.
 
 
  
  
'''(2)'''&nbsp; Richtig sind die <u>Antworten 2 und 4</u>:
 
* Der entscheidende Grund für die Duplex&ndash;Lücke ist es, einen Sicherheitsbuffer zwischen Uplink und Downlink zu schaffen.
 
*Aber auch Antwort 4 ist richtig: &nbsp; Funkmikrofone wurden und werden auch momentan noch mit Frequenzen im Bereich um 800 MHz betrieben, also bei solchen Frequenzen, die jetzt für LTE gebraucht werden.
 
*Wenn LTE endgültig flächendeckend ausgebaut ist, so kommt es zu Beeinträchtigungen von leistungsschwächeren Funkmikrofonen.
 
*Darüber hinaus ist für die Jahre nach 2015 der Einsatz von Veranstaltungstechnik auf den LTE–Frequenzen verboten. Unter anderem deshalb gibt es diese Duplex–Lücke, aber das ist nicht der eigentliche Grund, sondern ein nützlicher Nebeneffekt.
 
  
 +
'''(2)'''&nbsp; Correct are the <u>answers 2 and 4</u>:
 +
* The decisive reason for the "Duplex Gap" is to create a safety buffer between uplink and downlink.
 +
*But answer 4 is also correct: &nbsp; Radio microphones have been and are still operated with frequencies in the range around 800 MHz, i.e. at frequencies that are now needed for LTE.
 +
*When LTE is finally extended to cover entire areas, there will be interference with less powerful radio microphones.
 +
*In addition, the use of event technology on the LTE frequencies will be prohibited for the years after 2015.&nbsp; Among other things, this is also why there is this duplex gap, but that is not the real reason, it is a useful side effect.
  
  
'''(3)'''&nbsp; Richtig sind die <u>drei ersten Antworten</u>:
 
*OFDMA kommt im Downlink von LTE zum Einsatz, SC&ndash;FDMA im Uplink.
 
*Mehrantennensysteme (englisch: ''Multiple Input Multiple Output'', MIMO) kommen im Mobilfunk häufiger zum Einsatz, nicht nur bei LTE.
 
*Tatsächlich wird bei LTE aber auch CDMA eingesetzt, allerdings nur für Kontrollkanäle.
 
  
 +
'''(3)'''&nbsp; Correct are the <u>answers 1 to 3</u>:
 +
*OFDMA is used in the downlink of LTE, SC&ndash;FDMA in the uplink.
 +
*Multiple-input multiple-output (MIMO) systems are used more frequently in mobile communications, and not only in LTE.
 +
*In fact, CDMA is also used for LTE, but only for control channels.
  
  
'''(4)'''&nbsp; Richtig sind die <u>Antworten 1, 2 und 4</u>:  
+
'''(4)'''&nbsp; Correct are the <u>answers 1, 2 and 4</u>:  
*Der höherfrequente 2600 MHz–Bereich ist insbesondere aufgrund von Auflagen der Bundesregierung und wegen der geringeren Reichweite für Großstädte interessant.  
+
*The higher-frequency 2600 MHz range is particularly interesting for large cities due to conditions imposed by the federal government and because of the lower range.  
*Der nur aus gepaarten Frequenzen bestehende 800 MHz–Bereich wird vorwiegend für ländliche Gebiete genutzt werden.
+
*The 800 MHz range, which consists of paired frequencies only, will be used primarily for rural areas.
  
 
{{ML-Fuß}}
 
{{ML-Fuß}}
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[[Category:Exercises for Mobile Communications|^4.1 On the LTE standard^]]
+
[[Category:Mobile Communications: Exercises|^4.1 On the LTE Standard^]]

Latest revision as of 13:37, 23 March 2021

Some terms concerning  $\rm LTE$

Since 2011, mobile communications systems have already reached the fourth generation, without serious delays, as was the case with the second generation of mobile communications  $\rm (GSM)$  and even more so with the third generation  $\rm (UMTS)$. 

The development of new "releases" is constantly being driven forward by  $\text{3GPP}$.  This international consortium, which includes all major mobile operators and manufacturers worldwide, will continue to play a prominent role in mobile communications in the future.

LTE has been offered commercially since 2011, especially for sparsely populated rural areas without sufficient DSL broadband connections.  This 4G mobile communications standard is gradually becoming more widespread.

Currently (2017)  $\rm 5G$  is the all-dominant buzzword.  However, the author does not allow himself any more precise statements about the time of introduction than "very soon" or "as soon as possible".  More detailed information can be found  here.

Meanwhile (2021), we can say:  It was 2019, almost simultaneously in Korea and the US.




Notes:


Questionnaire

1

Which important innovations were described by 3GPP in the Release 8?

A purely packet-oriented transmission,
a high spectral efficiency,
frequency or bandwidth flexibility,
low energy consumption at the base stations.

2

What is the  "duplex gap"  of the LTE frequency band around  $800 \ \rm MHz$  for?

For the realization of the  "Cyclic Prefix",
to avoid interference between uplink and downlink,
to avoid overlapping between individual providers.
The duplex gap is also used to operate wireless microphones.

3

What methods and techniques does LTE mainly use?

OFDMA,
SC–FDMA,
MIMO,
CDMA.

4

How do the frequency bands by  $800 \ \rm MHz$  and by  $2.6 \ \rm GHz$  differ?

By different prices at the auction.
In the frequency band around  $800 \ \rm MHz$  there are only paired frequencies.
The frequency band around  $2.6 \ \rm GHz$  can only be used for FDD.
The areas of application differ fundamentally.


Solution

(1)  Correct are the answers 1 to 3, which also stand for the most important improvements through LTE:

  • Low power consumption at base stations is explicitly wrong, because the aim is to keep power consumption at the terminals as low as possible, for which even increased power consumption at base stations is accepted.


(2)  Correct are the answers 2 and 4:

  • The decisive reason for the "Duplex Gap" is to create a safety buffer between uplink and downlink.
  • But answer 4 is also correct:   Radio microphones have been and are still operated with frequencies in the range around 800 MHz, i.e. at frequencies that are now needed for LTE.
  • When LTE is finally extended to cover entire areas, there will be interference with less powerful radio microphones.
  • In addition, the use of event technology on the LTE frequencies will be prohibited for the years after 2015.  Among other things, this is also why there is this duplex gap, but that is not the real reason, it is a useful side effect.


(3)  Correct are the answers 1 to 3:

  • OFDMA is used in the downlink of LTE, SC–FDMA in the uplink.
  • Multiple-input multiple-output (MIMO) systems are used more frequently in mobile communications, and not only in LTE.
  • In fact, CDMA is also used for LTE, but only for control channels.


(4)  Correct are the answers 1, 2 and 4:

  • The higher-frequency 2600 MHz range is particularly interesting for large cities due to conditions imposed by the federal government and because of the lower range.
  • The 800 MHz range, which consists of paired frequencies only, will be used primarily for rural areas.