Difference between revisions of "Aufgaben:Exercise 4.4Z: Physical Channels in LTE"
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'''(1)''' Correct are the <u>solutions 3 and 4</u>: | '''(1)''' Correct are the <u>solutions 3 and 4</u>: | ||
| − | The assignment to | + | The assignment to $\rm D$ownlink or $\rm U\hspace{-0.05cm}$plink can be recognized by the second letter. It means: |
| − | *PDCCH: | + | *PDCCH: Physical Downlink Control Channel, |
| − | *PDSCH: | + | *PDSCH: Physical Downlink Shared Channel, |
| − | *PUCCH: | + | *PUCCH: Physical Uplink Control Channel, |
| − | *PUSCH: | + | *PUSCH: Physical Uplink Shared Channel. |
'''(2)''' Correct are the <u>solutions 2 and 4</u>: | '''(2)''' Correct are the <u>solutions 2 and 4</u>: | ||
| − | * | + | *$\rm C$ ⇒ "Control" as third letter indicates a control channel. |
| − | *User data are always transferred to the | + | *User data are always transferred to the "Shared Channels" ⇒ $\rm S$. |
'''(3)''' <u>All statements</u> are correct: | '''(3)''' <u>All statements</u> are correct: | ||
| − | *A block in the LTE downlink occupies $180 | + | *A block in the LTE downlink occupies $180 \ \rm kHz$ $($twelve subcarriers at $15 \ \rm kHz$ each$)$ and has a duration of $1 \ \rm ms$. |
*The assignment with PDCCH and PDSCH shows that the downlink is being considered. | *The assignment with PDCCH and PDSCH shows that the downlink is being considered. | ||
| − | *The reference symbols are needed to estimate the channel quality and calculate the | + | *The reference symbols are needed to estimate the channel quality and calculate the "Channel Quality Indicator" (CQI). |
| − | *These reference symbols are distributed over different frequencies or symbols (different times) in order to estimate the channel quality as comprehensively as possible. | + | *These reference symbols are distributed over different frequencies or symbols (different times) in order to estimate the channel quality as comprehensively as possible. |
| − | '''(4)''' The <u>statement 1</u> is true because only two of the $14$ columns are occupied by the control channel PDCCH. | + | '''(4)''' The <u>statement 1</u> is true because only two of the $14$ columns are occupied by the control channel PDCCH. <br>However, this result cannot be generalized. Rather, the division between PDCCH and PDSCH symbols is dependent on the user's requirements and therefore dynamic. |
| − | |||
| − | However, this result cannot be generalized. Rather, the division between PDCCH | ||
*For many users with a low data rate, the PDCCH would include three or four symbols, because this requires more intensive tuning than for a few concurrent users with high data rates. | *For many users with a low data rate, the PDCCH would include three or four symbols, because this requires more intensive tuning than for a few concurrent users with high data rates. | ||
| − | *The information "How many PDCCH symbols" is communicated to the terminal device via the | + | *The information "How many PDCCH symbols" is communicated to the terminal device via the "Physical Control Format Indicator Channel" (PCFICH). |
| − | '''(5)''' <u>All statements</u> | + | '''(5)''' <u>All statements above</u> are correct: |
| − | *The data rate of each user depends directly on the number of blocks of width $180 \ \rm kHz$ assigned to him. | + | *The data rate of each user depends directly on the number of blocks of width $180 \ \rm kHz$ assigned to him. |
| − | *The total LTI frequency width is between $1.4 \ \rm MHz$ and $20 \ \rm MHz$. | + | *The total LTI frequency width is between $1.4 \ \rm MHz$ and $20 \ \rm MHz$. |
| − | *In the frequency band of $1.4 \ | + | *In the frequency band of $1.4 \ \rm MHz$ six blocks of $180 \ \rm kHz$ are placed. |
*The overhead is thus $(1.4 - 6 \cdot 0.18)/1.4 \approx 22.8 \%$. | *The overhead is thus $(1.4 - 6 \cdot 0.18)/1.4 \approx 22.8 \%$. | ||
| − | *At $20 \ \rm MHz$ total frequency width, i.e. $100$ blocks, the overhead is $(20 - 100 \cdot 0.18)/26 = 10 | + | *At $20 \ \rm MHz$ total frequency width, i.e. $100$ blocks, the overhead is $(20 - 100 \cdot 0.18)/26 = 10 \%$. |
*The more blocks are available in total, the more can be allocated to each individual user if his channel is good and if many other users do not also have high demands at the same time. | *The more blocks are available in total, the more can be allocated to each individual user if his channel is good and if many other users do not also have high demands at the same time. | ||
Revision as of 17:08, 6 February 2021
Frequency/time assignment of the channels $\rm PDCCH$ and $\rm PDSCH$
The task refers to the two pages
All information required for the task can be found on these pages.
The diagram shows the assignment of the two channels $\rm PDCCH$ and $\rm PDSCH$ in frequency and time:
- One frequency block comprises $180 \ \rm kHz$ and is divided into twelve $15 \ \rm kHz$–subcarriers
- A subframe is one millisecond long and includes $14$ symbols.
- Red marked are the so-called reference symbols.
Notes:
- This task belongs to the chapter Physical Layer for LTE.
Questionnaire
Solution
(1) Correct are the solutions 3 and 4:
The assignment to $\rm D$ownlink or $\rm U\hspace{-0.05cm}$plink can be recognized by the second letter. It means:
- PDCCH: Physical Downlink Control Channel,
- PDSCH: Physical Downlink Shared Channel,
- PUCCH: Physical Uplink Control Channel,
- PUSCH: Physical Uplink Shared Channel.
(2) Correct are the solutions 2 and 4:
- $\rm C$ ⇒ "Control" as third letter indicates a control channel.
- User data are always transferred to the "Shared Channels" ⇒ $\rm S$.
(3) All statements are correct:
- A block in the LTE downlink occupies $180 \ \rm kHz$ $($twelve subcarriers at $15 \ \rm kHz$ each$)$ and has a duration of $1 \ \rm ms$.
- The assignment with PDCCH and PDSCH shows that the downlink is being considered.
- The reference symbols are needed to estimate the channel quality and calculate the "Channel Quality Indicator" (CQI).
- These reference symbols are distributed over different frequencies or symbols (different times) in order to estimate the channel quality as comprehensively as possible.
(4) The statement 1 is true because only two of the $14$ columns are occupied by the control channel PDCCH.
However, this result cannot be generalized. Rather, the division between PDCCH and PDSCH symbols is dependent on the user's requirements and therefore dynamic.
- For many users with a low data rate, the PDCCH would include three or four symbols, because this requires more intensive tuning than for a few concurrent users with high data rates.
- The information "How many PDCCH symbols" is communicated to the terminal device via the "Physical Control Format Indicator Channel" (PCFICH).
(5) All statements above are correct:
- The data rate of each user depends directly on the number of blocks of width $180 \ \rm kHz$ assigned to him.
- The total LTI frequency width is between $1.4 \ \rm MHz$ and $20 \ \rm MHz$.
- In the frequency band of $1.4 \ \rm MHz$ six blocks of $180 \ \rm kHz$ are placed.
- The overhead is thus $(1.4 - 6 \cdot 0.18)/1.4 \approx 22.8 \%$.
- At $20 \ \rm MHz$ total frequency width, i.e. $100$ blocks, the overhead is $(20 - 100 \cdot 0.18)/26 = 10 \%$.
- The more blocks are available in total, the more can be allocated to each individual user if his channel is good and if many other users do not also have high demands at the same time.
