Difference between revisions of "Aufgaben:Exercise 4.3: Subcarrier Mapping"
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For the number of interpolation points of DFT and IDFT, realistic numerical values of $K = 12$ and $N = 1024$ are assumed. | For the number of interpolation points of DFT and IDFT, realistic numerical values of $K = 12$ and $N = 1024$ are assumed. | ||
*The value $K = 12$ results from the fact that the symbols are "mapped" to a certain bandwidth by the "subcarrier mapping". The smallest addressable block for LTE is $180 \ \rm kHz$. With the subcarrier spacing of $15 \ \rm kHz$ the value $K = 12$ results. | *The value $K = 12$ results from the fact that the symbols are "mapped" to a certain bandwidth by the "subcarrier mapping". The smallest addressable block for LTE is $180 \ \rm kHz$. With the subcarrier spacing of $15 \ \rm kHz$ the value $K = 12$ results. | ||
| − | *With the number | + | *With the number $N$ of interpolation points of the IDFT $($with arrangement $\rm A)$ , up to $J = N/K$ users can thus be served simultaneously. For subcarrier mapping, there are three different approaches with DFDMA, IFDMA and LFDMA. |
*The first two users are shown in green and turquoise in the diagram. In subtask '''(5)''' you are to decide whether the sketch applies to DFDMA, IFDMA or LFDMA. | *The first two users are shown in green and turquoise in the diagram. In subtask '''(5)''' you are to decide whether the sketch applies to DFDMA, IFDMA or LFDMA. | ||
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<quiz display=simple> | <quiz display=simple> | ||
| − | {What do the outlined arrangements | + | {What do the outlined arrangements in the information section apply to? |
|type="()"} | |type="()"} | ||
- For the LTE downlink, | - For the LTE downlink, | ||
+ for the LTE uplink. | + for the LTE uplink. | ||
| − | {Which units are shown | + | {Which units are shown in the information section? |
|type="[]"} | |type="[]"} | ||
+ Arrangement $\rm A$ shows the transmitter of the LTE uplink. | + Arrangement $\rm A$ shows the transmitter of the LTE uplink. | ||
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$J \ = \ $ { 85 3% } | $J \ = \ $ { 85 3% } | ||
| − | {Which mapping is the graphic | + | {Which mapping is the graphic in the information section based on? |
|type="()"} | |type="()"} | ||
- Distributed Mapping (DFDMA), | - Distributed Mapping (DFDMA), | ||
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'''(1)''' <u>Proposed solution 2</u> is correct: | '''(1)''' <u>Proposed solution 2</u> is correct: | ||
| − | *Both arrangements show | + | *Both arrangements show "Single Carrier Frequency Division Multiple Access" $\text{(SC–FDMA)}$, recognisable by the DFT and IDFT blocks. |
| − | *The advantage over | + | *The advantage over "Orthogonal Frequency Division Multiple–Access" $\text{(OFDMA)}$ is the more favourable Peak–to–Average Power–Ratio $\text{(PAPR)}$. |
*A large PAPR means that the amplifiers must be operated below the saturation limit and thus at poorer efficiency in order to prevent excessive signal distortion. | *A large PAPR means that the amplifiers must be operated below the saturation limit and thus at poorer efficiency in order to prevent excessive signal distortion. | ||
*A lower PAPR also means longer battery life, an extremely important criterion for smartphones. | *A lower PAPR also means longer battery life, an extremely important criterion for smartphones. | ||
| − | *This is why SC-FDMA is used in the LTE uplink. For the downlink, the aspect mentioned here is less significant. | + | *This is why SC-FDMA is used in the LTE uplink. For the downlink, the aspect mentioned here is less significant. |
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'''(2)''' <u>Proposed solutions 1 and 2 </u>are correct: | '''(2)''' <u>Proposed solutions 1 and 2 </u>are correct: | ||
*While in OFDMA the data symbols to be transmitted directly generate the various subcarriers, in SC-FDMA a block of data symbols is first transformed into the frequency domain using DFT. | *While in OFDMA the data symbols to be transmitted directly generate the various subcarriers, in SC-FDMA a block of data symbols is first transformed into the frequency domain using DFT. | ||
| − | *To be able to transmit multiple users, $N > K$ must apply. An input block of a user thus consists of $K$ bits. It is thus obvious that arrangement $\rm A$ applies to the transmitter. | + | *To be able to transmit multiple users, $N > K$ must apply. An input block of a user thus consists of $K$ bits. It is thus obvious that arrangement $\rm A$ applies to the transmitter. |
| − | *Arrangement $\rm B$ | + | *Arrangement $\rm B$, on the other hand, describes the receiver of the LTE uplink and not the transmitter. |
'''(3)''' <u>Both statements</u> are correct: | '''(3)''' <u>Both statements</u> are correct: | ||
| − | *The measures are necessary to be able to process a continuous bit stream at the transmitter or to ensure a continuous bit stream at the receiver as well. | + | *The measures are necessary to be able to process a continuous bit stream at the transmitter, |
| + | *or to ensure a continuous bit stream at the receiver as well. | ||
| − | '''(4)''' The DFT also generates $K$ spectral values from $K$ input values. | + | '''(4)''' The DFT also generates $K$ spectral values from $K$ input values. |
| − | *The | + | *The subcarrier mapping does not change anything. |
| − | *Further users also occupy $K$ (bits) of the total of $N$ (bits). | + | *Further users also occupy $K$ (bits) of the total of $N$ (bits). |
| − | *Thus $J = N/K = 1024/12 = 85.333$ ⇒ $J \ \underline{= 85}$ users can be supplied. | + | *Thus $J = N/K = 1024/12 = 85.333$ ⇒ $J \ \underline{= 85}$ users can be supplied. |
'''(5)''' <u>Proposed solution 3</u> is correct: | '''(5)''' <u>Proposed solution 3</u> is correct: | ||
| − | *The graph conforms to the current 3gpp specification, which provides for | + | *The graph conforms to the current 3gpp specification, which provides for "Localized Mapping". |
| − | *Here, the $K$ modulation symbols are assigned to adjacent subcarriers. | + | *Here, the $K$ modulation symbols are assigned to adjacent subcarriers. |
| − | '''(6)''' <u> | + | '''(6)''' <u>Solutions 2 and 3</u> are correct: |
| − | *The realisation of DFT or IDFT as an (inverse) | + | *The realisation of DFT or IDFT as an (inverse) "Fast Fourier Transform" is only possible if the number of interpolation points is a power of two. |
| − | *For example, for $N = 1024$, but not for $K = 12$. | + | *For example, for $N = 1024$, but not for $K = 12$. |
{{ML-Fuß}} | {{ML-Fuß}} | ||
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| − | [[Category: | + | [[Category:Mobile Communications: Exercises|^4.3 Use of OFDMA and SC-FDMA |
^]] | ^]] | ||
Latest revision as of 14:43, 17 November 2022
Two SC–FDMA arrangements
The diagram shows two transmission schemes that play a role in connection with Long Term Evolution $\rm (LTE)$. These block diagrams are referred here neutrally as "arrangement $\rm A$" or "arrangement $\rm B$".
- The light grey blocks represent the transition from the time to the frequency domain.
- The dark grey blocks represent the transition from the frequency to the time domain.
We refer here to the following links:
- Discrete Fourier Transform ⇒ $\rm DFT$,
- Inverse Discrete Fourier Transform ⇒ $\rm IDFT$.
For the number of interpolation points of DFT and IDFT, realistic numerical values of $K = 12$ and $N = 1024$ are assumed.
- The value $K = 12$ results from the fact that the symbols are "mapped" to a certain bandwidth by the "subcarrier mapping". The smallest addressable block for LTE is $180 \ \rm kHz$. With the subcarrier spacing of $15 \ \rm kHz$ the value $K = 12$ results.
- With the number $N$ of interpolation points of the IDFT $($with arrangement $\rm A)$ , up to $J = N/K$ users can thus be served simultaneously. For subcarrier mapping, there are three different approaches with DFDMA, IFDMA and LFDMA.
- The first two users are shown in green and turquoise in the diagram. In subtask (5) you are to decide whether the sketch applies to DFDMA, IFDMA or LFDMA.
Note:
- The task belongs to the chapter The Application of OFDMA and SC-FDMA in LTE.
Questions
Solution
(1) Proposed solution 2 is correct:
- Both arrangements show "Single Carrier Frequency Division Multiple Access" $\text{(SC–FDMA)}$, recognisable by the DFT and IDFT blocks.
- The advantage over "Orthogonal Frequency Division Multiple–Access" $\text{(OFDMA)}$ is the more favourable Peak–to–Average Power–Ratio $\text{(PAPR)}$.
- A large PAPR means that the amplifiers must be operated below the saturation limit and thus at poorer efficiency in order to prevent excessive signal distortion.
- A lower PAPR also means longer battery life, an extremely important criterion for smartphones.
- This is why SC-FDMA is used in the LTE uplink. For the downlink, the aspect mentioned here is less significant.
(2) Proposed solutions 1 and 2 are correct:
- While in OFDMA the data symbols to be transmitted directly generate the various subcarriers, in SC-FDMA a block of data symbols is first transformed into the frequency domain using DFT.
- To be able to transmit multiple users, $N > K$ must apply. An input block of a user thus consists of $K$ bits. It is thus obvious that arrangement $\rm A$ applies to the transmitter.
- Arrangement $\rm B$, on the other hand, describes the receiver of the LTE uplink and not the transmitter.
(3) Both statements are correct:
- The measures are necessary to be able to process a continuous bit stream at the transmitter,
- or to ensure a continuous bit stream at the receiver as well.
(4) The DFT also generates $K$ spectral values from $K$ input values.
- The subcarrier mapping does not change anything.
- Further users also occupy $K$ (bits) of the total of $N$ (bits).
- Thus $J = N/K = 1024/12 = 85.333$ ⇒ $J \ \underline{= 85}$ users can be supplied.
(5) Proposed solution 3 is correct:
- The graph conforms to the current 3gpp specification, which provides for "Localized Mapping".
- Here, the $K$ modulation symbols are assigned to adjacent subcarriers.
(6) Solutions 2 and 3 are correct:
- The realisation of DFT or IDFT as an (inverse) "Fast Fourier Transform" is only possible if the number of interpolation points is a power of two.
- For example, for $N = 1024$, but not for $K = 12$.
