Difference between revisions of "Aufgaben:Exercise 2.1: Two-Dimensional Impulse Response"
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[[File:P_ID2144__Mob_A_2_1.png|right|frame|Two-dimensional impulse response]] | [[File:P_ID2144__Mob_A_2_1.png|right|frame|Two-dimensional impulse response]] | ||
The two-dimensional impulse response | The two-dimensional impulse response | ||
| − | $$h(\tau,\hspace{0.05cm}t) = \sum_{m = 1}^{M} z_m(t) \cdot {\rm \delta} (\tau - \tau_m)$$ | + | :$$h(\tau,\hspace{0.05cm}t) = \sum_{m = 1}^{M} z_m(t) \cdot {\rm \delta} (\tau - \tau_m)$$ |
| − | is to be analyzed according to the adjoining diagram. The two axes are time-discrete: | + | is to be analyzed according to the adjoining diagram. The two axes are time-discrete: |
* $\tau$ is the <i>delay</i> and can take values between $0$ and $6 \ {\rm µ s}$ in the example. | * $\tau$ is the <i>delay</i> and can take values between $0$ and $6 \ {\rm µ s}$ in the example. | ||
| − | * The | + | * The (absolute) time $t$ is related to the frequency of snapshots and characterizes the variation of the channel over time. We have $t = n \cdot T$, where $T \gg \tau_{\rm max}$ . |
The arrows in the graphic mark different Dirac functions with weights $1$ (red), $1/2$ (blue) and $1/4$ (green). This means that the delay $\tau$ is also discrete here. | The arrows in the graphic mark different Dirac functions with weights $1$ (red), $1/2$ (blue) and $1/4$ (green). This means that the delay $\tau$ is also discrete here. | ||
| − | When measuring the impulse responses at different times $t$ at intervals of one second, the resolution of the $\tau$ axis was | + | When measuring the impulse responses at different times $t$ at intervals of one second, the resolution of the $\tau$–axis was two microseconds $(\delta \tau = 2 \ \rm µ s)$. The echoes were not localized more precisely. |
In this task the following quantities are also referred to: | In this task the following quantities are also referred to: | ||
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\hspace{0.05cm},$$ | \hspace{0.05cm},$$ | ||
| − | + | * the approximation of the <i>coherence bandwidth</i> as the reciprocal of the maximal duration of the delay profile $h(\tau, t)$: | |
| − | * the approximation of the <i>coherence bandwidth</i> as the reciprocal of the maximal duration of the delay profile $h(\tau, t)$: | ||
:$$B_{\rm K} \hspace{0.01cm}' = \frac{1}{\tau_{\rm max} - \tau_{\rm min}} | :$$B_{\rm K} \hspace{0.01cm}' = \frac{1}{\tau_{\rm max} - \tau_{\rm min}} | ||
\hspace{0.05cm}.$$ | \hspace{0.05cm}.$$ | ||
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''Notes:'' | ''Notes:'' | ||
| − | * This task belongs to the chapter [[Mobile_Communications/ | + | * This task belongs to the chapter [[Mobile_Communications/General_Description_of_Time_Variant_Systems|General description of time–variant systems]]. |
| − | * More detailed information on various definitions for the coherence bandwidth can be found in chapter [[Mobile_Communications/ | + | * More detailed information on various definitions for the coherence bandwidth can be found in chapter [[Mobile_Communications/The_GWSSUS_Channel_Model|The GWSSUS channel model]], especially in the sample solution for the [[Aufgaben:Exercise_2.7Z:_Coherence_Bandwidth_of_the_LTI_Two-Path_Channel|Exercise 2.7Z]]. |
| − | * It should be noted that this is a constructed task. According to the above graph, the 2D impulse response changes significantly during the time span $T$ | + | * It should be noted that this is a constructed task. According to the above graph, the 2D impulse response changes significantly during the time span $T$. Therefore $T$ is to be interpreted here as very large, for example one hour. |
*In mobile radio, $h(\tau, t)$ changes in the millisecond range taking into account the Doppler effect, but the changes during this time are rather moderate. | *In mobile radio, $h(\tau, t)$ changes in the millisecond range taking into account the Doppler effect, but the changes during this time are rather moderate. | ||
Revision as of 16:45, 14 December 2020
Two-dimensional impulse response
The two-dimensional impulse response
- $$h(\tau,\hspace{0.05cm}t) = \sum_{m = 1}^{M} z_m(t) \cdot {\rm \delta} (\tau - \tau_m)$$
is to be analyzed according to the adjoining diagram. The two axes are time-discrete:
- $\tau$ is the delay and can take values between $0$ and $6 \ {\rm µ s}$ in the example.
- The (absolute) time $t$ is related to the frequency of snapshots and characterizes the variation of the channel over time. We have $t = n \cdot T$, where $T \gg \tau_{\rm max}$ .
The arrows in the graphic mark different Dirac functions with weights $1$ (red), $1/2$ (blue) and $1/4$ (green). This means that the delay $\tau$ is also discrete here.
When measuring the impulse responses at different times $t$ at intervals of one second, the resolution of the $\tau$–axis was two microseconds $(\delta \tau = 2 \ \rm µ s)$. The echoes were not localized more precisely.
In this task the following quantities are also referred to:
- the time-variant transfer function according to the definition
- $$H(f,\hspace{0.05cm} t) \hspace{0.2cm} \stackrel {f,\hspace{0.05cm}\tau}{\bullet\!\!-\!\!\!-\!\!\!-\!\!\circ} \hspace{0.2cm} h(\tau,\hspace{0.05cm}t) \hspace{0.05cm},$$
- the approximation of the coherence bandwidth as the reciprocal of the maximal duration of the delay profile $h(\tau, t)$:
- $$B_{\rm K} \hspace{0.01cm}' = \frac{1}{\tau_{\rm max} - \tau_{\rm min}} \hspace{0.05cm}.$$
Notes:
- This task belongs to the chapter General description of time–variant systems.
- More detailed information on various definitions for the coherence bandwidth can be found in chapter The GWSSUS channel model, especially in the sample solution for the Exercise 2.7Z.
- It should be noted that this is a constructed task. According to the above graph, the 2D impulse response changes significantly during the time span $T$. Therefore $T$ is to be interpreted here as very large, for example one hour.
- In mobile radio, $h(\tau, t)$ changes in the millisecond range taking into account the Doppler effect, but the changes during this time are rather moderate.
Questionnaire
Sample solution
(1) The message signal described in the equivalent low-pass band shall not have a bandwidth greater than $B_{\rm max} = 1/\delta \tau \ \underline {= 500 \ \rm kHz}$.
- This mathematical (two-sided) bandwidth of the low pass–signal is also the maximum physical (one-sided) bandwidth of the corresponding bandpass–signal.
(2) $H(f, t_{\rm 2}) = 1$ means in the time domain $h(\tau, t_{\rm 2}) = \delta(\tau)$.
- Only then the channel is ideal.
- You can see from the graph that this only applies to the time $t_{\rm 2} \ \underline {= 0}$.
(3) Distortions occur if at time $t$ the impulse response is composed of two or more Dirac functions ⇒ $t ≥ t_{\rm 3} \ \underline {= 3T}$.
- At time $t = T$ the signal $s(t)$ is delayed only by $2 \ \rm µ s$.
- At $t = 2T$ the amplitude is additionally reduced by $50 \%$ ($6 \ \ \rm dB$ loss).
(4) At time $t = 3T$ the two Dirac functions occur at $\tau_{\rm min} = 0$ and $\tau_{\rm max} = 4 \ \rm µ s$.
- The (simple approximation for the) coherence bandwidth is the reciprocal of the delay span of these Dirac functions
- $$B_{\rm K}\hspace{0.01cm}' = \frac{1}{4\,\,{\rm µ s} } \hspace{0.25cm} \underline{ = 250\,\,{\rm kHz}} \hspace{0.05cm}.$$
- As also at $t = 4T$ the Dirac functions are $4 \ \rm µ s$ apart, you also get $B_{\rm K} \hspace{0.01cm}' = \underline {250 \ \rm kHz}$ here .
- At $t = 5T$ the impulse response has an duration of $6 \ \ \rm µ s \ \ \Rightarrow \ {\it B}_{\rm K} \hspace{0.01cm}' \ \underline {\approx 166.7 \ \rm kHz}$.
(5) The impulse responses are identical at the times $5T$, $6T$ and $7T$ and consist of 3 Diracs each.
- Assuming that nothing changes in this respect for $t ≥ 8T$, you get $t_{\rm 5} \ \ \underline {= 5T}$.
(6) Solution 2 is correct:
- The temporal change of the impulse response, whose dynamics is expressed by the parameter $T$, must be slow in comparison to the maximum delay span of $h(\tau, t)$, which in this task equals $\tau_{\rm max} = 6 \ \rm µ s$: &e.g;
$$T \gg \tau_{\rm max}.$$
