Difference between revisions of "Aufgaben:Exercise 1.1: Basic Transmission Pulses"

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[[File:P_ID1256__Dig_A_1_1.png|right|frame|Considered basic transmission pulses]]
 
[[File:P_ID1256__Dig_A_1_1.png|right|frame|Considered basic transmission pulses]]
In this exercise, we examine the two transmitted signals  $s_{\rm R}(t)$  and  $s_{\rm C}(t)$  with square-wave and  $\cos^2$ basic transmission pulse, respectively, shown in the diagram. In particular, the following characteristics are to be calculated for the respective pulses  $g_s(t)$:   
+
In this exercise,  we examine the two transmitted signals  $s_{\rm R}(t)$  and  $s_{\rm C}(t)$  with rectangular resp. cosine–square basic transmission pulse,  shown in the diagram.  
 +
 
 +
In particular,  the following characteristics are to be calculated for the respective basic transmission pulses  $g_s(t)$:   
 
*the equivalent pulse duration of  $g_s(t)$:
 
*the equivalent pulse duration of  $g_s(t)$:
 
:$$\Delta t_{\rm S} =  \frac {\int ^{+\infty} _{-\infty} \hspace{0.15cm} g_s(t)\,{\rm
 
:$$\Delta t_{\rm S} =  \frac {\int ^{+\infty} _{-\infty} \hspace{0.15cm} g_s(t)\,{\rm
 
  d}t}{{\rm Max} \hspace{0.05cm}[g_s(t)]} \hspace{0.05cm},$$
 
  d}t}{{\rm Max} \hspace{0.05cm}[g_s(t)]} \hspace{0.05cm},$$
*the energy of the basic transmission pulse  $g_s(t)$:
+
*the energy of  $g_s(t)$:
 
:$$E_g =  \int^{+\infty} _{-\infty} g_s^2(t)\,{\rm
 
:$$E_g =  \int^{+\infty} _{-\infty} g_s^2(t)\,{\rm
 
  d}t \hspace{0.05cm},$$
 
  d}t \hspace{0.05cm},$$
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Always assume in your calculations that the two possible amplitude coefficients are equally likely and that the distance between adjacent symbols is  $T = 1 \ \rm  µ s$.  This corresponds to a bit rate of  $R = 1 \ \rm Mbit/s$.  
 
Always assume in your calculations that the two possible amplitude coefficients are equally likely and that the distance between adjacent symbols is  $T = 1 \ \rm  µ s$.  This corresponds to a bit rate of  $R = 1 \ \rm Mbit/s$.  
  
*The (positive) maximum value of the transmitted signal is the same in both cases
+
*The  (positive)  maximum value of the transmitted signal is the same in both cases:
 
:$$s_0 =  \sqrt{0.5\, {\rm W}}  \hspace{0.05cm}.$$
 
:$$s_0 =  \sqrt{0.5\, {\rm W}}  \hspace{0.05cm}.$$
*Assuming that the transmitter is terminated with a  $50\ \rm  Ω$  resistor, this corresponds to the following voltage value:
+
*Assuming that the transmitter is terminated with a  $50\ \rm  Ω$  resistor,  this corresponds to the following voltage value:
:$$s_0 =  \sqrt{0.5\, {\rm W}\hspace{0.05cm}.$$
+
:$$s_0^2 0.5\, {\rm W} \cdot 50\, {\rm \Omega} = 25\, {\rm V}^2 \hspace{0.15cm} \Rightarrow \hspace{0.15cm} s_0 =5\, {\rm V} \hspace{0.05cm}.$$
 
 
  
  
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''Notes:''
+
Notes:  
*The exercise belongs to the chapter  [[Digital_Signal_Transmission/System_Components_of_a_Baseband_Transmission_System|System Components of a Baseband Transmission System]].
+
*The exercise belongs to the chapter  [[Digital_Signal_Transmission/System_Components_of_a_Baseband_Transmission_System|"System Components of a Baseband Transmission System"]].
*Reference is made in particular to the section  [[Digital_Signal_Transmission/System_Components_of_a_Baseband_Transmission_System#Characteristics_of_the_digital_transmitter|Characteristics of the digital transmitter]].
+
*Reference is made in particular to the section  [[Digital_Signal_Transmission/System_Components_of_a_Baseband_Transmission_System#Characteristics_of_the_digital_transmitter|"Characteristics of the digital transmitter"]].  
 
 
*Given is the following indefinite integral:
 
*Given is the following indefinite integral:
 
:$$\int \cos^4(a  x)\,{\rm d}x = \frac{3}{8} \cdot x + \frac{1}{4a} \cdot \sin(2 a  x)+ \frac{1}{32a} \cdot \sin(4 a
 
:$$\int \cos^4(a  x)\,{\rm d}x = \frac{3}{8} \cdot x + \frac{1}{4a} \cdot \sin(2 a  x)+ \frac{1}{32a} \cdot \sin(4 a
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{What is the equivalent pulse duration  $\Delta t_{\rm S}$, normalized to the symbol duration  $T$?
+
{What is the equivalent pulse duration  $\Delta t_{\rm S}$,  normalized to the symbol duration  $T$?
 
|type="{}"}
 
|type="{}"}
$\text{for the signal}\ \ s_{\rm R}(t) \text{:} \ \ \Delta t_{\rm S}/T \ = \ $ { 1 3% }  
+
$\text{For the signal}\ \ s_{\rm R}(t) \text{:} \ \ \Delta t_{\rm S}/T \ = \ $ { 1 3% }  
$\text{for the signal}\ \ s_{\rm C}(t) \text{:} \ \ \Delta t_{\rm S}/T \ = \ $ { 0.5 3% }  
+
$\text{For the signal}\ \ s_{\rm C}(t) \text{:} \ \ \Delta t_{\rm S}/T \ = \ $ { 0.5 3% }  
  
{What is the energy of the rectangular basic transmission pulse??
+
{What is the energy of the rectangular basic transmission pulse  $g_s(t)$?
 
|type="{}"}
 
|type="{}"}
 
$E_g \ = \ $ { 0.5 } $\ \cdot 10^{-6}\ \rm Ws$  
 
$E_g \ = \ $ { 0.5 } $\ \cdot 10^{-6}\ \rm Ws$  
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$P_{\rm S} \ = \ $ { 0.25 3% } $\ \rm W$  
 
$P_{\rm S} \ = \ $ { 0.25 3% } $\ \rm W$  
  
{What is the energy of the  $\cos^2$ basic transmission pulse?
+
{What is the energy of the cosine–square basic transmission pulse  $g_s(t)$?
 
|type="{}"}
 
|type="{}"}
 
$E_g \ = \ $ { 0.1875 3% } $\ \cdot 10^{-6}\ \rm Ws$  
 
$E_g \ = \ $ { 0.1875 3% } $\ \cdot 10^{-6}\ \rm Ws$  
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===Solution===
 
===Solution===
 
{{ML-Kopf}}
 
{{ML-Kopf}}
'''(1)'''&nbsp;  <u>Solution 2</u> is correct:
+
'''(1)'''&nbsp;  <u>Solution 2</u>&nbsp; is correct:
*In both cases, the transmitted signal can be represented in the following form:
+
*In both cases,&nbsp; the transmitted signal can be represented in the following form:
 
:$$s(t) = \sum_{(\nu)} a_\nu \cdot g_s ( t - \nu \cdot T)$$
 
:$$s(t) = \sum_{(\nu)} a_\nu \cdot g_s ( t - \nu \cdot T)$$
*For the signal $s_{\rm R}(t)$, the amplitude coefficients $a_ν$ are either $0$ or $1$. Thus, a unipolar signal is present.
+
*For the signal $s_{\rm R}(t)$,&nbsp; the amplitude coefficients&nbsp; $a_ν$&nbsp; are either&nbsp; $0$&nbsp; or&nbsp; $1$.&nbsp; Thus,&nbsp; a unipolar signal is present.
*In contrast, for the bipolar signal $s_{\rm R}(t)$, $a_ν ∈ \{–1, +1\}$ holds.  
+
*In contrast,&nbsp; for the bipolar signal $s_{\rm R}(t)$ &nbsp; &rArr;  &nbsp;  $a_ν ∈ \{–1, +1\}$ holds.  
  
  
'''(2)'''&nbsp; The signal $s_{\rm R}(t)$ is NRZ rectangular.
+
'''(2)'''&nbsp; The signal&nbsp; $s_{\rm R}(t)$&nbsp; is NRZ&nbsp; ("non-return-to-zero")&nbsp; rectangular.
*Accordingly, both the absolute pulse duration $T_{\rm S}$ and the equivalent pulse duration $\Delta t_{\rm S}$ are equal to the symbol duration $T$:
+
*Accordingly,&nbsp; both the absolute pulse duration&nbsp; $T_{\rm S}$&nbsp; and the equivalent pulse duration&nbsp; $\Delta t_{\rm S}$&nbsp; are equal to the symbol duration&nbsp; $T$:
 
:$$T_{\rm S} / T = 1\hspace{0.05cm},\hspace{0.3cm}\Delta t_{\rm S} / T \hspace{0.1cm}\underline{ = 1 }\hspace{0.05cm}.$$
 
:$$T_{\rm S} / T = 1\hspace{0.05cm},\hspace{0.3cm}\Delta t_{\rm S} / T \hspace{0.1cm}\underline{ = 1 }\hspace{0.05cm}.$$
*The basic transmission pulse for the signal $s_{\rm C}(t)$ is:
+
*The basic transmission pulse for the signal&nbsp; $s_{\rm C}(t)$&nbsp; is:
 
:$$g_s(t)  =  \left\{ \begin{array}{c} s_0 \cdot \cos^2(\pi \cdot \frac{t}{T})  \\
 
:$$g_s(t)  =  \left\{ \begin{array}{c} s_0 \cdot \cos^2(\pi \cdot \frac{t}{T})  \\
 
  0 \\  \end{array} \right.\quad
 
  0 \\  \end{array} \right.\quad
\begin{array}{*{1}c} {\rm{f\ddot{u}r}}
+
\begin{array}{*{1}c} {\rm{for}}
 
\\    \\ \end{array}\begin{array}{*{20}c}
 
\\    \\ \end{array}\begin{array}{*{20}c}
 
-T/2 \le t \le +T/2 \hspace{0.05cm}, \\
 
-T/2 \le t \le +T/2 \hspace{0.05cm}, \\
{\rm sonst} \hspace{0.05cm}.  \\
+
{\rm else} \hspace{0.05cm}.  \\
 
\end{array}$$
 
\end{array}$$
*From the diagram on the information section, we can see that the following values apply to the $\cos^2$ pulse:
+
*From the diagram on the information section,&nbsp; we can see that the following values apply to the cosine&ndash;square pulse:
 
:$$T_{\rm S} / T = 1\hspace{0.05cm},\hspace{0.3cm}\Delta t_{\rm S} / T \hspace{0.1cm}\underline{ = 0.5} \hspace{0.05cm}.$$
 
:$$T_{\rm S} / T = 1\hspace{0.05cm},\hspace{0.3cm}\Delta t_{\rm S} / T \hspace{0.1cm}\underline{ = 0.5} \hspace{0.05cm}.$$
  
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'''(4)'''&nbsp; For a bipolar square wave signal, the following would apply:
+
'''(4)'''&nbsp; For a bipolar rectangular signal,&nbsp; the following would apply:
 
:$$s_{\rm R}^2(t)= s_0^2 = {\rm const.} \hspace{0.3cm}\Rightarrow \hspace{0.3cm} P_s =  s_0^2 \cdot
 
:$$s_{\rm R}^2(t)= s_0^2 = {\rm const.} \hspace{0.3cm}\Rightarrow \hspace{0.3cm} P_s =  s_0^2 \cdot
 
  \lim_{T_{\rm M} \to \infty} \frac{1}{T_{\rm M}} \cdot \int ^{T_{\rm M}/2} _{-T_{\rm M}/2} \,{\rm
 
  \lim_{T_{\rm M} \to \infty} \frac{1}{T_{\rm M}} \cdot \int ^{T_{\rm M}/2} _{-T_{\rm M}/2} \,{\rm
 
  d}t = s_0^2 \hspace{0.05cm}.$$
 
  d}t = s_0^2 \hspace{0.05cm}.$$
*However, since the signal $s_{\rm R}(t)$ is unipolar here, in half the time $s_{\rm R}(t)= 0$. Thus, we get:
+
*However,&nbsp; since the signal&nbsp; $s_{\rm R}(t)$ is&nbsp; unipolar here,&nbsp; in half the time $s_{\rm R}(t)= 0$.&nbsp; Thus,&nbsp; we get:
 
:$$P_{\rm S} = {1}/{2} \cdot s_0^2 \hspace{0.1cm}\underline{= 0.25 \,{\rm
 
:$$P_{\rm S} = {1}/{2} \cdot s_0^2 \hspace{0.1cm}\underline{= 0.25 \,{\rm
 
  W}}  \hspace{0.05cm}.$$
 
  W}}  \hspace{0.05cm}.$$
  
  
'''(5)'''&nbsp; For the energy of the $\cos^2$ pulse holds:
+
'''(5)'''&nbsp; For the energy of the cosine&ndash;square pulse holds:
 
:$$E_g =  \int^{+\infty} _{-\infty} g_s^2(t)\,{\rm
 
:$$E_g =  \int^{+\infty} _{-\infty} g_s^2(t)\,{\rm
 
  d}t = 2 \cdot s_0^2 \cdot \int^{T/2} _{0} \cos^4(\pi \cdot {t}/{T})\,{\rm
 
  d}t = 2 \cdot s_0^2 \cdot \int^{T/2} _{0} \cos^4(\pi \cdot {t}/{T})\,{\rm
 
  d}t \hspace{0.05cm}.$$
 
  d}t \hspace{0.05cm}.$$
*Here, the formula derived in point '''(3)''' and the symmetry of $g_s(t)$ about time $t = 0$ are considered.
+
*Here,&nbsp; the formula derived in subtask&nbsp; '''(3)'''&nbsp; and the symmetry of&nbsp; $g_s(t)$&nbsp; about time&nbsp; $t = 0$&nbsp; are considered.
*The integral is given in the task description, where $a = π/T$ is to be set:
+
*The integral is given in the task description,&nbsp; where $a = π/T$&nbsp; is to be set:
 
:$$E_g =    2  \cdot s_0^2 \cdot \left [ \frac{3}{8} \cdot t + \frac{T}{4\pi} \cdot \sin(2 \pi \frac{t}{T})+ \frac{T}{32\pi} \cdot
 
:$$E_g =    2  \cdot s_0^2 \cdot \left [ \frac{3}{8} \cdot t + \frac{T}{4\pi} \cdot \sin(2 \pi \frac{t}{T})+ \frac{T}{32\pi} \cdot
 
  \sin(4 \pi \frac{t}{T})\right ]_{0}^{T/2}\hspace{0.05cm}.$$
 
  \sin(4 \pi \frac{t}{T})\right ]_{0}^{T/2}\hspace{0.05cm}.$$
*The lower bound $t = 0$ always yields the result $0$. With respect to the upper bound, only the first term yields a result different from $0$. Thus:
+
*The lower bound&nbsp; $t = 0$&nbsp; always yields the result&nbsp; $0$. &nbsp; With respect to the upper bound,&nbsp; only the first term yields a result different from&nbsp; $0$.&nbsp; Thus:
 
:$$E_g =    2  \cdot s_0^2 \cdot  \frac{3}{8} \cdot \frac{T}{2} = \frac{3}{8} \cdot 5 \cdot 10^{-7}\, {\rm
 
:$$E_g =    2  \cdot s_0^2 \cdot  \frac{3}{8} \cdot \frac{T}{2} = \frac{3}{8} \cdot 5 \cdot 10^{-7}\, {\rm
 
  Ws} \hspace{0.1cm}\underline{ = 0.1875 \cdot 10^{-6}\, {\rm
 
  Ws} \hspace{0.1cm}\underline{ = 0.1875 \cdot 10^{-6}\, {\rm

Latest revision as of 14:13, 9 May 2022


Considered basic transmission pulses

In this exercise,  we examine the two transmitted signals  $s_{\rm R}(t)$  and  $s_{\rm C}(t)$  with rectangular resp. cosine–square basic transmission pulse,  shown in the diagram.

In particular,  the following characteristics are to be calculated for the respective basic transmission pulses  $g_s(t)$: 

  • the equivalent pulse duration of  $g_s(t)$:
$$\Delta t_{\rm S} = \frac {\int ^{+\infty} _{-\infty} \hspace{0.15cm} g_s(t)\,{\rm d}t}{{\rm Max} \hspace{0.05cm}[g_s(t)]} \hspace{0.05cm},$$
  • the energy of  $g_s(t)$:
$$E_g = \int^{+\infty} _{-\infty} g_s^2(t)\,{\rm d}t \hspace{0.05cm},$$
  • the power of the transmitted signal  $s(t)$:
$$P_{\rm S} = \lim_{T_{\rm M} \to \infty} \frac{1}{+T_{\rm M}} \cdot \int^{+T_{\rm M}/2} _{-T_{\rm M}/2} s^2(t)\,{\rm d}t \hspace{0.05cm}.$$


Always assume in your calculations that the two possible amplitude coefficients are equally likely and that the distance between adjacent symbols is  $T = 1 \ \rm µ s$.  This corresponds to a bit rate of  $R = 1 \ \rm Mbit/s$.

  • The  (positive)  maximum value of the transmitted signal is the same in both cases:
$$s_0 = \sqrt{0.5\, {\rm W}} \hspace{0.05cm}.$$
  • Assuming that the transmitter is terminated with a  $50\ \rm Ω$  resistor,  this corresponds to the following voltage value:
$$s_0^2 = 0.5\, {\rm W} \cdot 50\, {\rm \Omega} = 25\, {\rm V}^2 \hspace{0.15cm} \Rightarrow \hspace{0.15cm} s_0 =5\, {\rm V} \hspace{0.05cm}.$$



Notes:

$$\int \cos^4(a x)\,{\rm d}x = \frac{3}{8} \cdot x + \frac{1}{4a} \cdot \sin(2 a x)+ \frac{1}{32a} \cdot \sin(4 a x)\hspace{0.05cm}.$$


Questions

1

Are $s_{\rm R}(t)$ and $s_{\rm C}(t)$ unipolar or bipolar signals?

$s_{\rm R}(t)$  is a bipolar signal and  $s_{\rm C}(t)$  is a unipolar signal.
$s_{\rm C}(t)$  is a bipolar signal and  $s_{\rm R}(t)$  is a unipolar signal.

2

What is the equivalent pulse duration  $\Delta t_{\rm S}$,  normalized to the symbol duration  $T$?

$\text{For the signal}\ \ s_{\rm R}(t) \text{:} \ \ \Delta t_{\rm S}/T \ = \ $

$\text{For the signal}\ \ s_{\rm C}(t) \text{:} \ \ \Delta t_{\rm S}/T \ = \ $

3

What is the energy of the rectangular basic transmission pulse  $g_s(t)$?

$E_g \ = \ $

$\ \cdot 10^{-6}\ \rm Ws$

4

What is the power of the rectangular transmitted signal  $s_{\rm R}(t)$?

$P_{\rm S} \ = \ $

$\ \rm W$

5

What is the energy of the cosine–square basic transmission pulse  $g_s(t)$?

$E_g \ = \ $

$\ \cdot 10^{-6}\ \rm Ws$

6

What is the power of the transmitted signal  $s_{\rm C}(t)$?

$P_{\rm S} \ = \ $

$\ \rm W$


Solution

(1)  Solution 2  is correct:

  • In both cases,  the transmitted signal can be represented in the following form:
$$s(t) = \sum_{(\nu)} a_\nu \cdot g_s ( t - \nu \cdot T)$$
  • For the signal $s_{\rm R}(t)$,  the amplitude coefficients  $a_ν$  are either  $0$  or  $1$.  Thus,  a unipolar signal is present.
  • In contrast,  for the bipolar signal $s_{\rm R}(t)$   ⇒   $a_ν ∈ \{–1, +1\}$ holds.


(2)  The signal  $s_{\rm R}(t)$  is NRZ  ("non-return-to-zero")  rectangular.

  • Accordingly,  both the absolute pulse duration  $T_{\rm S}$  and the equivalent pulse duration  $\Delta t_{\rm S}$  are equal to the symbol duration  $T$:
$$T_{\rm S} / T = 1\hspace{0.05cm},\hspace{0.3cm}\Delta t_{\rm S} / T \hspace{0.1cm}\underline{ = 1 }\hspace{0.05cm}.$$
  • The basic transmission pulse for the signal  $s_{\rm C}(t)$  is:
$$g_s(t) = \left\{ \begin{array}{c} s_0 \cdot \cos^2(\pi \cdot \frac{t}{T}) \\ 0 \\ \end{array} \right.\quad \begin{array}{*{1}c} {\rm{for}} \\ \\ \end{array}\begin{array}{*{20}c} -T/2 \le t \le +T/2 \hspace{0.05cm}, \\ {\rm else} \hspace{0.05cm}. \\ \end{array}$$
  • From the diagram on the information section,  we can see that the following values apply to the cosine–square pulse:
$$T_{\rm S} / T = 1\hspace{0.05cm},\hspace{0.3cm}\Delta t_{\rm S} / T \hspace{0.1cm}\underline{ = 0.5} \hspace{0.05cm}.$$


(3)  For the energy of the rectangular pulse holds:

$$E_g = \int^{+\infty} _{-\infty} g_s^2(t)\,{\rm d}t = s_0^2 \cdot T = 0.5\, {\rm W} \cdot 1\, {\rm µ s} \hspace{0.1cm}\underline{= 0.5 \cdot 10^{-6}\, {\rm Ws}}\hspace{0.05cm}.$$


(4)  For a bipolar rectangular signal,  the following would apply:

$$s_{\rm R}^2(t)= s_0^2 = {\rm const.} \hspace{0.3cm}\Rightarrow \hspace{0.3cm} P_s = s_0^2 \cdot \lim_{T_{\rm M} \to \infty} \frac{1}{T_{\rm M}} \cdot \int ^{T_{\rm M}/2} _{-T_{\rm M}/2} \,{\rm d}t = s_0^2 \hspace{0.05cm}.$$
  • However,  since the signal  $s_{\rm R}(t)$ is  unipolar here,  in half the time $s_{\rm R}(t)= 0$.  Thus,  we get:
$$P_{\rm S} = {1}/{2} \cdot s_0^2 \hspace{0.1cm}\underline{= 0.25 \,{\rm W}} \hspace{0.05cm}.$$


(5)  For the energy of the cosine–square pulse holds:

$$E_g = \int^{+\infty} _{-\infty} g_s^2(t)\,{\rm d}t = 2 \cdot s_0^2 \cdot \int^{T/2} _{0} \cos^4(\pi \cdot {t}/{T})\,{\rm d}t \hspace{0.05cm}.$$
  • Here,  the formula derived in subtask  (3)  and the symmetry of  $g_s(t)$  about time  $t = 0$  are considered.
  • The integral is given in the task description,  where $a = π/T$  is to be set:
$$E_g = 2 \cdot s_0^2 \cdot \left [ \frac{3}{8} \cdot t + \frac{T}{4\pi} \cdot \sin(2 \pi \frac{t}{T})+ \frac{T}{32\pi} \cdot \sin(4 \pi \frac{t}{T})\right ]_{0}^{T/2}\hspace{0.05cm}.$$
  • The lower bound  $t = 0$  always yields the result  $0$.   With respect to the upper bound,  only the first term yields a result different from  $0$.  Thus:
$$E_g = 2 \cdot s_0^2 \cdot \frac{3}{8} \cdot \frac{T}{2} = \frac{3}{8} \cdot 5 \cdot 10^{-7}\, {\rm Ws} \hspace{0.1cm}\underline{ = 0.1875 \cdot 10^{-6}\, {\rm Ws}}\hspace{0.05cm}.$$


(6)  The following relationship holds for the bipolar signal $s_{\rm C}(t)$:

$$P_{\rm S} = \frac{ E_g}{T} = \frac{ 1.875 \cdot 10^{-7}\, {\rm Ws}}{10^{-6}\, {\rm s}}\hspace{0.1cm}\underline{ = 0.1875 \,{\rm W}} \hspace{0.05cm}.$$