Difference between revisions of "Aufgaben:Exercise 4.3: Natural and Discrete Sampling"
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[[File:EN_Mod_A_4_3.png|right|frame|For natural and discrete sampling]] | [[File:EN_Mod_A_4_3.png|right|frame|For natural and discrete sampling]] | ||
| − | Ideal sampling can be described in | + | Ideal sampling can be described in time domain by multiplying the analog source signal $q(t)$ by a [[Signal_Representation/Time_Discrete_Signal_Representation#Diracpulse_in_Time_and_in_Frequency_Domain|Dirac comb]] $p_δ(t)$ : |
:$$ q_{\rm A}(t) = p_{\delta}(t) \cdot q(t) \hspace{0.05cm}.$$ | :$$ q_{\rm A}(t) = p_{\delta}(t) \cdot q(t) \hspace{0.05cm}.$$ | ||
| − | Dirac | + | Dirac impulses – infinitely narrow and infinitely high – and accordingly also the "Dirac comb" $p_δ(t)$ cannot be realized in practice, however. |
| − | :$$ p_{\rm R}(t) = \left [ \frac{1}{T_{\rm A}} \cdot p_{\rm \delta}(t) \right ]\star g_{\rm R}(t)\hspace{0. | + | |
| − | g_{\rm R}(t) = \left\{ \begin{array}{l} 1 \\ 1/2 \\ 0 \\ \end{array} \right.\quad \begin{array}{*{5}c}{\rm{ | + | Here we must assume instead the "rectangular pulse comb" $p_{\rm R}(t)$ where the following relation holds: |
| + | :$$ p_{\rm R}(t) = \left [ \frac{1}{T_{\rm A}} \cdot p_{\rm \delta}(t) \right ]\star g_{\rm R}(t)\hspace{0.4cm}\text{with}\hspace{0.4cm} | ||
| + | g_{\rm R}(t) = \left\{ \begin{array}{l} 1 \\ 1/2 \\ 0 \\ \end{array} \right.\quad \begin{array}{*{5}c}{\rm{f\ddot{u}r}} \\{\rm{f\ddot{u}r}} \\{\rm{f\ddot{u}r}} \\ \end{array}\begin{array}{*{10}c} {\hspace{0.04cm}\left|\hspace{0.06cm} t \hspace{0.05cm} \right|} < T_{\rm R}/2\hspace{0.05cm}, \\ {\hspace{0.04cm}\left|\hspace{0.06cm} t \hspace{0.05cm} \right|} = T_{\rm R}/2\hspace{0.05cm}, \\ {\hspace{0.005cm}\left|\hspace{0.06cm} t \hspace{0.05cm} \right|} > T_{\rm R}/2\hspace{0.05cm}. \\ \end{array}$$ | ||
The duration $T_{\rm R}$ of a rectangular pulse $g_{\rm R}(t)$ should be (significantly) smaller than the distance $T_{\rm A}$ of two samples. | The duration $T_{\rm R}$ of a rectangular pulse $g_{\rm R}(t)$ should be (significantly) smaller than the distance $T_{\rm A}$ of two samples. | ||
| − | In the diagram this ratio is chosen | + | In the diagram this ratio is chosen with $T_{\rm R}/T_{\rm A} = 0.5$ very large to make the difference between "natural sampling" and "discrete sampling" especially clear: |
| − | * In natural sampling, the sampled signal $q_{\rm A}(t)$ is equal to the product of | + | * In natural sampling, the sampled signal $q_{\rm A}(t)$ is equal to the product of the rectangular pulse comb $p_{\rm R}(t)$ and the analog source signal $q(t)$: |
:$$q_{\rm A}(t) = p_{\rm R}(t) \cdot q(t) = \left [ \frac{1}{T_{\rm A}} \cdot p_{\rm \delta}(t) \star g_{\rm R}(t)\right ]\cdot q(t)\hspace{0.05cm}.$$ | :$$q_{\rm A}(t) = p_{\rm R}(t) \cdot q(t) = \left [ \frac{1}{T_{\rm A}} \cdot p_{\rm \delta}(t) \star g_{\rm R}(t)\right ]\cdot q(t)\hspace{0.05cm}.$$ | ||
| − | * In contrast, the corresponding equation for discrete sampling is: | + | * In contrast, the corresponding equation for discrete sampling is: |
:$$ q_{\rm A}(t) = \left [ \frac{1}{T_{\rm A}} \cdot p_{\rm \delta}(t) \cdot q(t)\right ]\star g_{\rm R}(t)\hspace{0.05cm}.$$ | :$$ q_{\rm A}(t) = \left [ \frac{1}{T_{\rm A}} \cdot p_{\rm \delta}(t) \cdot q(t)\right ]\star g_{\rm R}(t)\hspace{0.05cm}.$$ | ||
| − | In the graph, these signals are sketched in blue (natural sampling) and green (discrete sampling) respectively. | + | In the graph, these signals are sketched in blue (natural sampling) and green (discrete sampling) respectively. |
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| − | |||
| − | |||
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| − | |||
| − | |||
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| + | For signal reconstruction, a rectangular low-pass filter $H(f)$ with cutoff frequency $f_{\rm G} = f_{\rm A}/2$ and gain $T_{\rm A}/T_{\rm R}$ is used in the passband: | ||
| + | :$$H(f) = \left\{ \begin{array}{l} T_{\rm A}/T_{\rm R} \\ 0 \\ \end{array} \right.\quad \begin{array}{*{5}c}{\rm{f\ddot{u}r}} \\{\rm{f\ddot{u}r}} \\ \end{array}\begin{array}{*{10}c} {\hspace{0.04cm}\left| \hspace{0.005cm} f\hspace{0.05cm} \right| < f_{\rm A}/2}\hspace{0.05cm}, \\ {\hspace{0.04cm}\left| \hspace{0.005cm} f\hspace{0.05cm} \right| > f_{\rm A}/2}\hspace{0.05cm}. \\ \end{array}$$ | ||
Hints: | Hints: | ||
| − | *The exercise belongs to the chapter [[Modulation_Methods/Pulse_Code_Modulation| | + | *The exercise belongs to the chapter [[Modulation_Methods/Pulse_Code_Modulation|"Pulse Code Modulation"]]. |
| − | *Reference is made in particular to the page [[Modulation_Methods/Pulse_Code_Modulation#Natural_and_discrete_sampling|Natural and discrete sampling]]. | + | *Reference is made in particular to the page [[Modulation_Methods/Pulse_Code_Modulation#Natural_and_discrete_sampling|"Natural and discrete sampling"]]. |
*The sampled source signal is denoted by $q_{\rm A}(t)$ and its spectral function by $Q_{\rm A}(f)$. | *The sampled source signal is denoted by $q_{\rm A}(t)$ and its spectral function by $Q_{\rm A}(f)$. | ||
| − | * Sampling is always performed at $ν | + | * Sampling is always performed at $ν \cdot T_{\rm A}$. |
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<quiz display=simple> | <quiz display=simple> | ||
| − | {Let $T_{\rm R}/T_{\rm A} = 0.5$. For this, give the normalized spectrum $G_{\rm R}(f)/T_{\rm A}$ What spectral value occurs at $f = 0$ ? | + | {Let $T_{\rm R}/T_{\rm A} = 0.5$. For this, give the normalized spectrum $G_{\rm R}(f)/T_{\rm A}$. What spectral value occurs at $f = 0$ ? |
|type="{}"} | |type="{}"} | ||
$G_{\rm R}(f=0)/T_{\rm A} \ = \ $ { 0.5 3% } | $G_{\rm R}(f=0)/T_{\rm A} \ = \ $ { 0.5 3% } | ||
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|type="[]"} | |type="[]"} | ||
- It holds $Q_{\rm A}(f) = P_{\rm δ}(f) ∗ Q(f)$. | - It holds $Q_{\rm A}(f) = P_{\rm δ}(f) ∗ Q(f)$. | ||
| − | + It holds $Q_{\rm A}(f) = \big[{\rm δ}(f) | + | + It holds $Q_{\rm A}(f) = \big[{\rm δ}(f) \cdot (G_{\rm R}(f)/T_{\rm A})\big] ∗ Q(f)$. |
| − | - It holds $Q_{\rm A}(f) = \big[P_{\rm δ}(f) ∗ Q(f)\big] | + | - It holds $Q_{\rm A}(f) = \big[P_{\rm δ}(f) ∗ Q(f)\big] \cdot (G_{\rm R}(f)/T_{\rm A})$. |
| − | { For natural sampling | + | { For natural sampling: Is the specified low-pass suitable for interpolation? |
|type="()"} | |type="()"} | ||
+ Yes. | + Yes. | ||
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|type="[]"} | |type="[]"} | ||
- It holds $Q_{\rm A}(f) = P_{\rm δ}(f) ∗ Q(f)$. | - It holds $Q_{\rm A}(f) = P_{\rm δ}(f) ∗ Q(f)$. | ||
| − | - It holds $Q_{\rm A}(f) = \big[{\rm δ}(f) | + | - It holds $Q_{\rm A}(f) = \big[{\rm δ}(f) \cdot (G_{\rm R}(f)/T_{\rm A})\big] ∗ Q(f)$. |
| − | + It holds $Q_{\rm A}(f) = \big[P_{\rm δ}(f) ∗ Q(f)\big] | + | + It holds $Q_{\rm A}(f) = \big[P_{\rm δ}(f) ∗ Q(f)\big] \cdot (G_{\rm R}(f)/T_{\rm A})$. |
| − | {For discrete sampling | + | {For discrete sampling: Is the specified low-pass suitable for interpolation? |
|type="()"} | |type="()"} | ||
- Yes. | - Yes. | ||
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===Solution=== | ===Solution=== | ||
{{ML-Kopf}} | {{ML-Kopf}} | ||
| − | '''(1)''' The spectrum of the | + | '''(1)''' The spectrum of the rectangular pulse $g_{\rm R}(t)$ with amplitude $1$ and duration $T_{\rm R}$ is: |
| − | :$$ G_{\rm R}(f) = T_{\rm R} \cdot {\rm | + | :$$ G_{\rm R}(f) = T_{\rm R} \cdot {\rm sinc}(f T_{\rm R}) \hspace{0.3cm} {\rm with}\hspace{0.3cm} {\rm sinc}(x) = \sin(\pi x)/(\pi x)\hspace{0.3cm} |
| − | \ | + | \Rightarrow \hspace{0.3cm} \frac{G_{\rm R}(f)}{T_{\rm A}} = \frac{T_{\rm R}}{T_{\rm A}} \cdot {\rm sinc}(f T_{\rm R})\hspace{0.3cm} \Rightarrow \hspace{0.3cm} \frac{G_{\rm R}(f = 0)}{T_{\rm A}} =\frac{T_{\rm R}}{T_{\rm A}}\hspace{0.15cm}\underline { = 0.5} \hspace{0.05cm}.$$ |
| − | |||
| − | |||
| − | '''(2)''' The correct solution is the <u>second suggested solution</u>: | + | '''(2)''' The correct solution is the <u>second suggested solution</u>: |
| − | *From the given equation in the time domain, the convolution theorem gives: | + | *From the given equation in the time domain, the convolution theorem gives: |
:$$q_{\rm A}(t) = \left [ \frac{1}{T_{\rm A}} \cdot p_{\rm \delta}(t) \star g_{\rm R}(t)\right ]\cdot q(t) \hspace{0.3cm} | :$$q_{\rm A}(t) = \left [ \frac{1}{T_{\rm A}} \cdot p_{\rm \delta}(t) \star g_{\rm R}(t)\right ]\cdot q(t) \hspace{0.3cm} | ||
\Rightarrow \hspace{0.3cm}Q_{\rm A}(f) = \left [ \frac{1}{T_{\rm A}}\cdot P_{\rm \delta}(f) \cdot G_{\rm R}(f) \right ] \star Q(f) = \left [ P_{\rm \delta}(f) \cdot \frac{G_{\rm R}(f)}{{T_{\rm A}}} \right ] \star Q(f) \hspace{0.05cm}.$$ | \Rightarrow \hspace{0.3cm}Q_{\rm A}(f) = \left [ \frac{1}{T_{\rm A}}\cdot P_{\rm \delta}(f) \cdot G_{\rm R}(f) \right ] \star Q(f) = \left [ P_{\rm \delta}(f) \cdot \frac{G_{\rm R}(f)}{{T_{\rm A}}} \right ] \star Q(f) \hspace{0.05cm}.$$ | ||
| − | *The first proposed solution is valid only for ideal sampling (with a Dirac | + | *The first proposed solution is valid only for ideal sampling (with a Dirac comb) and the last one for discrete sampling. |
| − | |||
| − | '''(3)''' The answer is <u>YES</u>: | + | '''(3)''' The answer is <u>YES</u>: |
| − | * Starting from the result of the subtask '''(2)''' using the spectral function of the Dirac | + | * Starting from the result of the subtask '''(2)''' using the spectral function of the Dirac comb, we obtain. |
:$$Q_{\rm A}(f) = \left [ P_{\rm \delta}(f) \cdot \frac{G_{\rm R}(f)}{{T_{\rm A}}} \right ] \star Q(f)= \left [ \frac{G_{\rm R}(f)}{{T_{\rm A}}} \cdot \sum_{\mu = -\infty}^{+\infty} \delta(f - \mu \cdot f_{\rm A})\right ] \star Q(f) \hspace{0.05cm}.$$ | :$$Q_{\rm A}(f) = \left [ P_{\rm \delta}(f) \cdot \frac{G_{\rm R}(f)}{{T_{\rm A}}} \right ] \star Q(f)= \left [ \frac{G_{\rm R}(f)}{{T_{\rm A}}} \cdot \sum_{\mu = -\infty}^{+\infty} \delta(f - \mu \cdot f_{\rm A})\right ] \star Q(f) \hspace{0.05cm}.$$ | ||
| − | *When the sampling theorem is satisfied and the low-pass filter is correct | + | *When the sampling theorem is satisfied and the low-pass filter is correct: <br>From the infinite convolution products only the convolution product with $μ = 0$ lie in the passband. |
| − | *Taking into account the gain factor $T_{\rm A}/T_{\rm R}$ we thus obtain for the spectrum at the filter output: | + | *Taking into account the gain factor $T_{\rm A}/T_{\rm R}$, we thus obtain for the spectrum at the filter output: |
| − | :$$V(f) = \frac{T_{\rm A}}{T_{\rm R}} \cdot \left [ \frac{G_{\rm R}(f = 0)}{{T_{\rm A}} \cdot \delta(f )\right ] \star Q(f)= Q(f) \hspace{0.05cm}.$$ | + | :$$V(f) = \frac{T_{\rm A}}{T_{\rm R}} \cdot \left [ \frac{G_{\rm R}(f = 0)}{{T_{\rm A}}} \cdot \delta(f )\right ] \star Q(f)= Q(f) \hspace{0.05cm}.$$ |
| − | '''(4)''' The<u> last suggested solution</u> is correct. | + | '''(4)''' The <u>last suggested solution</u> is correct. |
| − | *Shifting the factor $1/T_{\rm A}$ to the rectangular pulse, we obtain with discrete sampling using the convolution theorem: | + | *Shifting the factor $1/T_{\rm A}$ to the rectangular pulse, we obtain with discrete sampling using the convolution theorem: |
:$$ q_{\rm A}(t) = \big [ p_{\rm \delta}(t)\cdot q(t) \big ] \star \frac{g_{\rm R}(t)}{T_{\rm A}}\hspace{0.3cm} | :$$ q_{\rm A}(t) = \big [ p_{\rm \delta}(t)\cdot q(t) \big ] \star \frac{g_{\rm R}(t)}{T_{\rm A}}\hspace{0.3cm} | ||
\Rightarrow \hspace{0.3cm}Q_{\rm A}(f)= \big [ P_{\rm \delta}(f)\star Q(f) \big ] \cdot \frac{G_{\rm R}(f)}{T_{\rm A}}\hspace{0.05cm}.$$ | \Rightarrow \hspace{0.3cm}Q_{\rm A}(f)= \big [ P_{\rm \delta}(f)\star Q(f) \big ] \cdot \frac{G_{\rm R}(f)}{T_{\rm A}}\hspace{0.05cm}.$$ | ||
| − | '''(5)''' The answer is <u>NO</u>: | + | '''(5)''' The answer is <u>NO</u>: |
*The weighting function $G_{\rm R}(f)$ now involves the inner kernel $(μ = 0)$ of the convolution product. | *The weighting function $G_{\rm R}(f)$ now involves the inner kernel $(μ = 0)$ of the convolution product. | ||
| − | *All other terms $(μ ≠ 0)$ are eliminated by the low-pass filter. One obtains here in the relevant range $|f| < f_{\rm A}/2$: | + | *All other terms $(μ ≠ 0)$ are eliminated by the low-pass filter. |
| − | :$$V(f) = \frac{T_{\rm A}}{T_{\rm R}} \cdot \frac{G_{\rm R}(f )}{{T_{\rm A}}} \cdot Q(f) = 2 \cdot 0.5 \cdot {\rm | + | *One obtains here in the relevant range $|f| < f_{\rm A}/2$: |
| − | *If no additional equalization is provided here, the higher frequencies are attenuated according to the $\rm | + | :$$V(f) = \frac{T_{\rm A}}{T_{\rm R}} \cdot \frac{G_{\rm R}(f )}{{T_{\rm A}}} \cdot Q(f) = 2 \cdot 0.5 \cdot {\rm sinc}(f T_{\rm R})\cdot Q(f) \hspace{0.3cm}\Rightarrow \hspace{0.3cm}V(f) = Q(f) \cdot {\rm sinc}(f T_{\rm R})\hspace{0.05cm}.$$ |
| + | *If no additional equalization is provided here, the higher frequencies are attenuated according to the $\rm sinc$ function. | ||
*The highest signal frequency $(f = f_{\rm A}/2)$ is attenuated the most here: | *The highest signal frequency $(f = f_{\rm A}/2)$ is attenuated the most here: | ||
| − | :$$V(f = | + | :$$V(f = f_{\rm A}/2) = Q( f_{\rm A}/2) \cdot {\rm sinc}( \frac{T_{\rm R}}{2 \cdot T_{\rm A}})= |
| − | Q( | + | Q( f_{\rm A}/2) \cdot \frac{\sin(\pi/4)}{\pi/4}\approx 0.9 \cdot Q( f_{\rm A}/2) \hspace{0.05cm}.$$ |
{{ML-Fuß}} | {{ML-Fuß}} | ||
Latest revision as of 17:13, 8 April 2022
For natural and discrete sampling
Ideal sampling can be described in time domain by multiplying the analog source signal $q(t)$ by a Dirac comb $p_δ(t)$ :
- $$ q_{\rm A}(t) = p_{\delta}(t) \cdot q(t) \hspace{0.05cm}.$$
Dirac impulses – infinitely narrow and infinitely high – and accordingly also the "Dirac comb" $p_δ(t)$ cannot be realized in practice, however.
Here we must assume instead the "rectangular pulse comb" $p_{\rm R}(t)$ where the following relation holds:
- $$ p_{\rm R}(t) = \left [ \frac{1}{T_{\rm A}} \cdot p_{\rm \delta}(t) \right ]\star g_{\rm R}(t)\hspace{0.4cm}\text{with}\hspace{0.4cm} g_{\rm R}(t) = \left\{ \begin{array}{l} 1 \\ 1/2 \\ 0 \\ \end{array} \right.\quad \begin{array}{*{5}c}{\rm{f\ddot{u}r}} \\{\rm{f\ddot{u}r}} \\{\rm{f\ddot{u}r}} \\ \end{array}\begin{array}{*{10}c} {\hspace{0.04cm}\left|\hspace{0.06cm} t \hspace{0.05cm} \right|} < T_{\rm R}/2\hspace{0.05cm}, \\ {\hspace{0.04cm}\left|\hspace{0.06cm} t \hspace{0.05cm} \right|} = T_{\rm R}/2\hspace{0.05cm}, \\ {\hspace{0.005cm}\left|\hspace{0.06cm} t \hspace{0.05cm} \right|} > T_{\rm R}/2\hspace{0.05cm}. \\ \end{array}$$
The duration $T_{\rm R}$ of a rectangular pulse $g_{\rm R}(t)$ should be (significantly) smaller than the distance $T_{\rm A}$ of two samples.
In the diagram this ratio is chosen with $T_{\rm R}/T_{\rm A} = 0.5$ very large to make the difference between "natural sampling" and "discrete sampling" especially clear:
- In natural sampling, the sampled signal $q_{\rm A}(t)$ is equal to the product of the rectangular pulse comb $p_{\rm R}(t)$ and the analog source signal $q(t)$:
- $$q_{\rm A}(t) = p_{\rm R}(t) \cdot q(t) = \left [ \frac{1}{T_{\rm A}} \cdot p_{\rm \delta}(t) \star g_{\rm R}(t)\right ]\cdot q(t)\hspace{0.05cm}.$$
- In contrast, the corresponding equation for discrete sampling is:
- $$ q_{\rm A}(t) = \left [ \frac{1}{T_{\rm A}} \cdot p_{\rm \delta}(t) \cdot q(t)\right ]\star g_{\rm R}(t)\hspace{0.05cm}.$$
In the graph, these signals are sketched in blue (natural sampling) and green (discrete sampling) respectively.
For signal reconstruction, a rectangular low-pass filter $H(f)$ with cutoff frequency $f_{\rm G} = f_{\rm A}/2$ and gain $T_{\rm A}/T_{\rm R}$ is used in the passband:
- $$H(f) = \left\{ \begin{array}{l} T_{\rm A}/T_{\rm R} \\ 0 \\ \end{array} \right.\quad \begin{array}{*{5}c}{\rm{f\ddot{u}r}} \\{\rm{f\ddot{u}r}} \\ \end{array}\begin{array}{*{10}c} {\hspace{0.04cm}\left| \hspace{0.005cm} f\hspace{0.05cm} \right| < f_{\rm A}/2}\hspace{0.05cm}, \\ {\hspace{0.04cm}\left| \hspace{0.005cm} f\hspace{0.05cm} \right| > f_{\rm A}/2}\hspace{0.05cm}. \\ \end{array}$$
Hints:
- The exercise belongs to the chapter "Pulse Code Modulation".
- Reference is made in particular to the page "Natural and discrete sampling".
- The sampled source signal is denoted by $q_{\rm A}(t)$ and its spectral function by $Q_{\rm A}(f)$.
- Sampling is always performed at $ν \cdot T_{\rm A}$.
Questions
Solution
(1) The spectrum of the rectangular pulse $g_{\rm R}(t)$ with amplitude $1$ and duration $T_{\rm R}$ is:
- $$ G_{\rm R}(f) = T_{\rm R} \cdot {\rm sinc}(f T_{\rm R}) \hspace{0.3cm} {\rm with}\hspace{0.3cm} {\rm sinc}(x) = \sin(\pi x)/(\pi x)\hspace{0.3cm} \Rightarrow \hspace{0.3cm} \frac{G_{\rm R}(f)}{T_{\rm A}} = \frac{T_{\rm R}}{T_{\rm A}} \cdot {\rm sinc}(f T_{\rm R})\hspace{0.3cm} \Rightarrow \hspace{0.3cm} \frac{G_{\rm R}(f = 0)}{T_{\rm A}} =\frac{T_{\rm R}}{T_{\rm A}}\hspace{0.15cm}\underline { = 0.5} \hspace{0.05cm}.$$
(2) The correct solution is the second suggested solution:
- From the given equation in the time domain, the convolution theorem gives:
- $$q_{\rm A}(t) = \left [ \frac{1}{T_{\rm A}} \cdot p_{\rm \delta}(t) \star g_{\rm R}(t)\right ]\cdot q(t) \hspace{0.3cm} \Rightarrow \hspace{0.3cm}Q_{\rm A}(f) = \left [ \frac{1}{T_{\rm A}}\cdot P_{\rm \delta}(f) \cdot G_{\rm R}(f) \right ] \star Q(f) = \left [ P_{\rm \delta}(f) \cdot \frac{G_{\rm R}(f)}{{T_{\rm A}}} \right ] \star Q(f) \hspace{0.05cm}.$$
- The first proposed solution is valid only for ideal sampling (with a Dirac comb) and the last one for discrete sampling.
(3) The answer is YES:
- Starting from the result of the subtask (2) using the spectral function of the Dirac comb, we obtain.
- $$Q_{\rm A}(f) = \left [ P_{\rm \delta}(f) \cdot \frac{G_{\rm R}(f)}{{T_{\rm A}}} \right ] \star Q(f)= \left [ \frac{G_{\rm R}(f)}{{T_{\rm A}}} \cdot \sum_{\mu = -\infty}^{+\infty} \delta(f - \mu \cdot f_{\rm A})\right ] \star Q(f) \hspace{0.05cm}.$$
- When the sampling theorem is satisfied and the low-pass filter is correct:
From the infinite convolution products only the convolution product with $μ = 0$ lie in the passband. - Taking into account the gain factor $T_{\rm A}/T_{\rm R}$, we thus obtain for the spectrum at the filter output:
- $$V(f) = \frac{T_{\rm A}}{T_{\rm R}} \cdot \left [ \frac{G_{\rm R}(f = 0)}{{T_{\rm A}}} \cdot \delta(f )\right ] \star Q(f)= Q(f) \hspace{0.05cm}.$$
(4) The last suggested solution is correct.
- Shifting the factor $1/T_{\rm A}$ to the rectangular pulse, we obtain with discrete sampling using the convolution theorem:
- $$ q_{\rm A}(t) = \big [ p_{\rm \delta}(t)\cdot q(t) \big ] \star \frac{g_{\rm R}(t)}{T_{\rm A}}\hspace{0.3cm} \Rightarrow \hspace{0.3cm}Q_{\rm A}(f)= \big [ P_{\rm \delta}(f)\star Q(f) \big ] \cdot \frac{G_{\rm R}(f)}{T_{\rm A}}\hspace{0.05cm}.$$
(5) The answer is NO:
- The weighting function $G_{\rm R}(f)$ now involves the inner kernel $(μ = 0)$ of the convolution product.
- All other terms $(μ ≠ 0)$ are eliminated by the low-pass filter.
- One obtains here in the relevant range $|f| < f_{\rm A}/2$:
- $$V(f) = \frac{T_{\rm A}}{T_{\rm R}} \cdot \frac{G_{\rm R}(f )}{{T_{\rm A}}} \cdot Q(f) = 2 \cdot 0.5 \cdot {\rm sinc}(f T_{\rm R})\cdot Q(f) \hspace{0.3cm}\Rightarrow \hspace{0.3cm}V(f) = Q(f) \cdot {\rm sinc}(f T_{\rm R})\hspace{0.05cm}.$$
- If no additional equalization is provided here, the higher frequencies are attenuated according to the $\rm sinc$ function.
- The highest signal frequency $(f = f_{\rm A}/2)$ is attenuated the most here:
- $$V(f = f_{\rm A}/2) = Q( f_{\rm A}/2) \cdot {\rm sinc}( \frac{T_{\rm R}}{2 \cdot T_{\rm A}})= Q( f_{\rm A}/2) \cdot \frac{\sin(\pi/4)}{\pi/4}\approx 0.9 \cdot Q( f_{\rm A}/2) \hspace{0.05cm}.$$
