Difference between revisions of "Aufgaben:Exercise 2.8: Asymmetrical Channel"

Revision as of 21:56, 20 December 2021

Equivalent low-pass signal
in the complex plane

A cosine-shaped source signal $q(t)$ with amplitude $A_{\rm N}$ and frequency $f_{\rm N}$ is DSB amplitude modulated, such that the modulated signal is given by:

$$ s(t) = \big[ q(t) + A_{\rm T}\big] \cdot \cos(2 \pi \cdot f_{\rm T} \cdot t ) \hspace{0.05cm}.$$

The transmission channel exhibits linear distortions:

While the lower sideband $($LSB frequency: $f_{\rm T} - f_{\rm N})$ and the carrier are transmitted undistorted,
the upper sideband $($USB-Frequenz: $f_{\rm T} + f_{\rm N})$ is weighted with the attenuation factor $α_{\rm O} = 0.25$ .

The graph shows the locus curve, i.e., the representation of the equivalent low-pass signal $r_{\rm TP}(t)$ in the complex plane.

Evaluating the signal $r(t)$ with an ideal envelope demodulator, we obtain a sink signal $v(t)$, which can be approximated as follows:

$$v(t) = 2.424 \,{\rm V} \cdot \cos(\omega_{\rm N} \cdot t ) -0.148 \,{\rm V} \cdot \cos(2\omega_{\rm N} \cdot t )+ 0.056 \,{\rm V} \cdot \cos(3\omega_{\rm N} \cdot t )-\text{ ...}$$

For this measurement, the message frequency $f_{\rm N} = 2 \ \rm kHz$ was used.

In subtask (7) the signal-to-noise power ratio $\rm (SNR)$ should be calculated as follows:

$$ \rho_{v } = \frac{P_{v 1}}{P_{\varepsilon }} \hspace{0.05cm}.$$

Here, $P_{v1} = α^2 · P_q$ and $P_ε$ denote the "powers" of both signals:

$$ v_1(t) = 2.424 \,{\rm V} \cdot \cos(\omega_{\rm N} \cdot t )\hspace{0.05cm},$$

$$ \varepsilon(t) = v(t) - v_1(t) \approx -0.148 \,{\rm V} \cdot \cos(2\omega_{\rm N} \cdot t )+ 0.056 \,{\rm V} \cdot \cos(3\omega_{\rm N} \cdot t ) \hspace{0.05cm}.$$

Hints:

This exercise belongs to the chapter Envelope Demodulation.
Particular reference is made to the page Description using the equivalent low-pass signal.

Questions

$r_{\rm TP}(t=0) \ = \ $

$\ \rm V$

$A_{\rm T} \ = \ $

$\ \rm V$

$A_{\rm N} \ = \ $

$\ \rm V$

$t_1 \ = \ $

$\ \rm ms$

$t_2 \ = \ $

$\ \rm ms$

$a(t = t_2) \ = \ $

$\ \rm V$

$ϕ(t = t_2)\ = \ $

$\ \rm degrees$

$K \ = \ $

$\ \text{%}$

$ρ_v \ = \ $

$K \ = \ $

$\ \text{%}$

Solution

(1) For a cosine-shaped source signal and attenuation of the upper sideband, it holds that:

$$ r_{\rm TP}(t) = A_{\rm T} + \frac{A_{\rm N}}{2} \cdot \alpha_{\rm O} \cdot{\rm e}^{{\rm j} \cdot \hspace{0.03cm}\omega_{\rm N}\cdot t} + \frac{A_{\rm N}}{2} \cdot{\rm e}^{-{\rm j} \cdot \hspace{0.03cm}\omega_{\rm N}\cdot t}\hspace{0.05cm}.$$

At time $t = 0$ all vectors point in the direction of the real axis.
Thus $r_{\rm TP}(t = 0)\hspace{0.15cm}\underline { = 15 \ \rm V}$ can be read from the graph on the exercise page.

(2) The carrier amplitude is defined by the center of the ellipse: $A_{\rm T}\hspace{0.15cm}\underline { = 10 \ \rm V}$.

From the equation given in the first subtask, the amplitude $A_{\rm N}$ can thus also be calculated:

$$ \frac{A_{\rm N}}{2} \cdot ( 1+ \alpha_0) = r_{\rm TP}(t= 0) - A_{\rm T} = 5 \,{\rm V}\hspace{0.3cm} \Rightarrow \hspace{0.3cm}A_{\rm N} \hspace{0.15cm}\underline {= 8 \,{\rm V}} \hspace{0.05cm}.$$

The point marked (2) can be used as a check:

$$\frac{A_{\rm N}}{2} \cdot ( 1- \alpha_0) = 3 \,{\rm V}\hspace{0.3cm} \Rightarrow \hspace{0.3cm}A_{\rm N} = 8 \,{\rm V} \hspace{0.05cm}.$$

(3) The necessary time for one cycle t $t_1$ is equal to the period of the source signal, i.e.,

$$t_1= 1/f_{\rm N} \hspace{0.15cm}\underline {=0.5 \ \rm ms}.$$

(4) Since the lower sideband is larger than the upper sideband, the peak of the pointer composite moves clockwise around the ellipse.

Point (2) is first reached at time $t_2 = 3/4 · t_1\hspace{0.15cm}\underline { = 0.375 \ \rm ms}$ .

Calculation of $t_2$ and $t_3$

(5) The pointer length at time $t_2$ can be determined with the Pythagorean Theorem :

$$ a(t = t_2) = \sqrt{(10 \,{\rm V})^2 + (3 \,{\rm V})^2}\hspace{0.15cm}\underline { = 10.44 \,{\rm V}}\hspace{0.05cm}.$$

The phase function is:

$$\phi(t = t_2) = {\rm arctan} \frac{3 \,{\rm V}}{10 \,{\rm V}} \hspace{0.15cm}\underline {= 16.7^{\circ}}\hspace{0.05cm}.$$

The maximum phase $ϕ_{\rm max}$ is slightly larger. It occurs (with a positive sign) at time $t_3 < t_2$ when a straight line from the origin is tangent to the ellipse.
By setting up the ellipse equation, this point $(x_3$, $y_3)$ can be accurately calculated analytically.
From this, the following would hold for the maximum phase:

$\phi_{\rm max} = {\rm arctan} \ {y_3}/{x_3} \hspace{0.05cm}.$

(6) The distortion factors of second and third ordern can be obtained from the given equation for nbsp; $v(t)$ $($valid for $f_{\rm N} = 2 \ \rm kHz)$ , and are:

$$ K_2 = \frac{0.148 \,{\rm V}}{2.424 \,{\rm V}} = 0.061, \hspace{0.3cm} K_3 = \frac{0.056 \,{\rm V}}{2.424 \,{\rm V}} = 0.023 \hspace{0.05cm}.$$

Thus for the total distortion factor we get:

$$K = \sqrt{K_2^2 + K_3^2 }\hspace{0.15cm}\underline { \approx 6.6 \%}.$$

(7) Frot he power of the useful signal and the interference signal, we obtain:

$$ P_{v 1} = \frac{(2.424 \,{\rm V})^2}{2} = 2.94 \,{\rm V}^2\hspace{0.05cm},\hspace{0.3cm} P_{\varepsilon} = \frac{(-0.148 \,{\rm V})^2}{2} + \frac{(0.056 \,{\rm V})^2}{2}= 0.0125 \,{\rm V}^2\hspace{0.05cm}$$

This gives the signal-to-noise power ratio $\rm (SNR)$:

$$\rho_{v} = \frac{P_{v 1}}{P_{\varepsilon }}= \frac{(2.94 \,{\rm V})^2}{0.0125 \,{\rm V}^2} \hspace{0.15cm}\underline {\approx 230} = \frac{1}{K^2} \hspace{0.05cm}.$$

If, on the other hand, the amplitude distortion were also assigned to the error signal, we would arrive at a much smaller $\rm SNR$.
When $P_q = A_{\rm N}^2/2 = 8 \ \rm V^2$ and $P_{\varepsilon}\hspace{0.02cm}' = \overline{(v(t)-q(t))^2} = {1}/{2}\cdot ( 4 \,{\rm V} - 2.424 \,{\rm V})^2 + P_{\varepsilon}= 1.254 \,{\rm V}^2$ one would get:

$$\rho_{v }\hspace{0.02cm}' = \frac{8 \,{\rm V}^2}{1.254 \,{\rm V}^2} \approx 6.4\hspace{0.05cm}.$$

(8) All calculations are valid regardless of the message frequency $f_{\rm N}$ if the attenuation factor of the upper sideband remains at $α_{\rm O} = 0.25$ .

Thus, the same distortion factor $K\hspace{0.15cm}\underline { \approx 6.6 \%}$ is obtained for $f_{\rm N} = 4 \ \rm kHz$ .

@@ Line 78: / Line 78: @@
 ===Solution===
 {{ML-Kopf}}
-'''(1)'''&nbsp;  Bei cosinusförmigem Quellensignal und Dämpfung des oberen Seitenbandes gilt:
+'''(1)'''&nbsp;  For a cosine-shaped source signal and attenuation of the upper sideband, it holds that:
 :$$ r_{\rm TP}(t) = A_{\rm T} + \frac{A_{\rm N}}{2} \cdot \alpha_{\rm O} \cdot{\rm e}^{{\rm j} \cdot \hspace{0.03cm}\omega_{\rm N}\cdot t} + \frac{A_{\rm N}}{2} \cdot{\rm e}^{-{\rm j} \cdot \hspace{0.03cm}\omega_{\rm N}\cdot t}\hspace{0.05cm}.$$
-*Zum Zeitpunkt&nbsp; $t = 0$&nbsp; zeigen alle Vektoren in Richtung der reellen Achse.
+*At time &nbsp; $t = 0$&nbsp; all vectors point in the direction of the real axis.
-*Somit kann aus der Grafik auf der Angabenseite&nbsp; $r_{\rm TP}(t = 0)\hspace{0.15cm}\underline { = 15 \ \rm V}$&nbsp; abgelesen werden.
+*Thus &nbsp; $r_{\rm TP}(t = 0)\hspace{0.15cm}\underline { = 15 \ \rm V}$&nbsp; can be read from the graph on the exercise page.
-'''(2)'''&nbsp;  Die Trägeramplitude ist durch den Ellipsenmittelpunkt festgelegt:&nbsp; $A_{\rm T}\hspace{0.15cm}\underline { = 10 \ \rm V}$.
+'''(2)'''&nbsp;  The carrier amplitude is defined by the center of the ellipse:
-*Aus der in der ersten Teilaufgabe angegebenen Gleichung kann somit auch die Amplitude&nbsp; $A_{\rm N}$&nbsp; berechnet werden:
+&nbsp; $A_{\rm T}\hspace{0.15cm}\underline { = 10 \ \rm V}$.
+*From the equation given in the first subtask, the amplitude&nbsp; $A_{\rm N}$&nbsp; can thus also be calculated:
 :$$ \frac{A_{\rm N}}{2} \cdot ( 1+ \alpha_0) = r_{\rm TP}(t= 0) - A_{\rm T} = 5 \,{\rm V}\hspace{0.3cm} \Rightarrow \hspace{0.3cm}A_{\rm N} \hspace{0.15cm}\underline {= 8 \,{\rm V}} \hspace{0.05cm}.$$
-*Zur Kontrolle kann der in der Grafik markierte Punkt&nbsp; '''(2)'''&nbsp; herangezogen werden:
+*The point marked &nbsp; '''(2)'''&nbsp; can be used as a check:
 :$$\frac{A_{\rm N}}{2} \cdot ( 1- \alpha_0) = 3 \,{\rm V}\hspace{0.3cm} \Rightarrow \hspace{0.3cm}A_{\rm N} = 8 \,{\rm V} \hspace{0.05cm}.$$
-'''(3)'''&nbsp;  Die für einen Umlauf benötigte Zeit&nbsp; $t_1$&nbsp; ist gleich der Periodendauer des Quellensignals, also
+'''(3)'''&nbsp;  The necessary time for one cycle t&nbsp; $t_1$&nbsp; is equal to the period of the source signal, i.e.,
 :$$t_1= 1/f_{\rm N} \hspace{0.15cm}\underline {=0.5 \ \rm ms}.$$
-'''(4)'''&nbsp;  Da das USB größer ist als das OSB, bewegt sich die Spitze des Zeigerverbundes auf der Ellipse im Uhrzeigersinn.
+'''(4)'''&nbsp;  Since the lower sideband is larger than the upper sideband, the peak of the pointer composite moves clockwise around the ellipse.
-*Der Punkt&nbsp; '''(2)'''&nbsp; wird zum Zeitpunkt&nbsp; $t_2 = 3/4 · t_1\hspace{0.15cm}\underline { = 0.375 \ \rm ms}$&nbsp; zum ersten Mal erreicht.
+*Point&nbsp; '''(2)'''&nbsp; is first reached at time&nbsp; $t_2 = 3/4 · t_1\hspace{0.15cm}\underline { = 0.375 \ \rm ms}$&nbsp; .
-[[File:P_ID1039__Mod_A_2_8_e.png|right|frame|Zur Berechnung von&nbsp; $t_2$&nbsp; und&nbsp; $t_3$]]
+[[File:P_ID1039__Mod_A_2_8_e.png|right|frame|Calculation of &nbsp; $t_2$&nbsp; and&nbsp; $t_3$]]
-'''(5)'''&nbsp;  Die Zeigerlänge zur Zeit&nbsp; $t_2$&nbsp; kann mit dem&nbsp; [https://de.wikipedia.org/wiki/Satz_des_Pythagoras Satz von Pythagoras]&nbsp; bestimmt werden:
+'''(5)'''&nbsp;  The pointer length at time &nbsp; $t_2$&nbsp; can be determined with the &nbsp; [https://en.wikipedia.org/wiki/Pythagorean_theorem Pythagorean Theorem]&nbsp;:
 :$$ a(t = t_2) = \sqrt{(10 \,{\rm V})^2 + (3 \,{\rm V})^2}\hspace{0.15cm}\underline { = 10.44 \,{\rm V}}\hspace{0.05cm}.$$
-*Für die Phasenfunktion gilt:
+*The phase function is:
 :$$\phi(t = t_2) = {\rm arctan} \frac{3 \,{\rm V}}{10 \,{\rm V}} \hspace{0.15cm}\underline {= 16.7^{\circ}}\hspace{0.05cm}.$$
-*Die maximale Phase&nbsp; $ϕ_{\rm max}$&nbsp; ist geringfügig größer.&nbsp; Sie tritt (mit positivem Vorzeichen) zum Zeitpunkt&nbsp; $t_3 < t_2$&nbsp; dann auf, wenn eine Gerade vom Koordinatenursprung die Ellipse tangiert.
+*The maximum phase&nbsp; $ϕ_{\rm max}$&nbsp; is slightly larger.&nbsp; It occurs (with a positive sign) at time &nbsp; $t_3 < t_2$&nbsp; when a straight line from the origin is tangent to the ellipse.
-*Durch Aufstellen der Ellipsengleichung kann dieser Punkt&nbsp; $(x_3$,&nbsp; $y_3)$&nbsp; analytisch exakt berechnet werden.
+*By setting up the ellipse equation, this point &nbsp; $(x_3$,&nbsp; $y_3)$&nbsp; can be accurately calculated analytically.
-*Daraus würde für die maximale Phase gelten:&nbsp; $\phi_{\rm max} = {\rm arctan} \ {y_3}/{x_3} \hspace{0.05cm}.$
+*From this, the following would hold for the maximum phase:
+:&nbsp; $\phi_{\rm max} = {\rm arctan} \ {y_3}/{x_3} \hspace{0.05cm}.$
-'''(6)'''&nbsp;  Die Klirrfaktoren zweiter und dritter Ordnung können aus der angegebenen Gleichung für&nbsp; $v(t)$&nbsp; $($gültig für $f_{\rm N} = 2 \ \rm kHz)$&nbsp; ermittelt werden und  lauten:
+'''(6)'''&nbsp;  The distortion factors of second and third ordern can be obtained from the given equation for nbsp; $v(t)$&nbsp; $($valid for $f_{\rm N} = 2 \ \rm kHz)$&nbsp;, and are:
 :$$ K_2 = \frac{0.148 \,{\rm V}}{2.424 \,{\rm V}} = 0.061, \hspace{0.3cm} K_3 = \frac{0.056 \,{\rm V}}{2.424 \,{\rm V}} = 0.023 \hspace{0.05cm}.$$
-*Damit erhält man für den Gesamtklirrfaktor:
+*Thus for the total distortion factor we get:
 :$$K = \sqrt{K_2^2 + K_3^2 }\hspace{0.15cm}\underline { \approx 6.6 \%}.$$
-'''(7)'''&nbsp;  Für die Leistungen von Nutz– und Störsignal erhält man:
+'''(7)'''&nbsp;  Frot he power of the useful signal and the interference signal, we obtain:
 :$$ P_{v 1} = \frac{(2.424 \,{\rm V})^2}{2} = 2.94 \,{\rm V}^2\hspace{0.05cm},\hspace{0.3cm} P_{\varepsilon} = \frac{(-0.148 \,{\rm V})^2}{2} + \frac{(0.056 \,{\rm V})^2}{2}= 0.0125 \,{\rm V}^2\hspace{0.05cm}$$
-*Damit ergibt sich für das Signal–zu–Stör–Leistungsverhältnis&nbsp; $\rm (SNR)$:
+*This gives the signal-to-noise power ratio &nbsp; $\rm (SNR)$:
 :$$\rho_{v} = \frac{P_{v 1}}{P_{\varepsilon }}= \frac{(2.94 \,{\rm V})^2}{0.0125 \,{\rm V}^2} \hspace{0.15cm}\underline {\approx 230} = \frac{1}{K^2} \hspace{0.05cm}.$$
-*Würde man dagegen die Amplitudenverfälschung ebenfalls dem Fehlersignal zuweisen, so käme man zu einem deutlich kleineren&nbsp; $\rm SNR$.&nbsp; &nbsp;
+*If, on the other hand, the amplitude distortion were also assigned to the error signal, we would arrive at a much smaller&nbsp; $\rm SNR$.
-*Mit $P_q = A_{\rm N}^2/2 = 8 \ \rm V^2$&nbsp; und&nbsp; $P_{\varepsilon}\hspace{0.02cm}' = \overline{(v(t)-q(t))^2} = {1}/{2}\cdot ( 4 \,{\rm V} - 2.424 \,{\rm V})^2 + P_{\varepsilon}= 1.254 \,{\rm V}^2$&nbsp; würde man dann erhalten:
+*When $P_q = A_{\rm N}^2/2 = 8 \ \rm V^2$&nbsp; and&nbsp; $P_{\varepsilon}\hspace{0.02cm}' = \overline{(v(t)-q(t))^2} = {1}/{2}\cdot ( 4 \,{\rm V} - 2.424 \,{\rm V})^2 + P_{\varepsilon}= 1.254 \,{\rm V}^2$&nbsp; one would get:
 :$$\rho_{v }\hspace{0.02cm}' = \frac{8 \,{\rm V}^2}{1.254 \,{\rm V}^2} \approx 6.4\hspace{0.05cm}.$$
-'''(8)'''&nbsp;  Alle Berechnungen gelten unabhängig von der Nachrichtenfrequenz&nbsp; $f_{\rm N}$, wenn der Dämpfungsfaktor des OSB weiterhin&nbsp; $α_{\rm O} = 0.25$&nbsp; beträgt.
+'''(8)'''&nbsp;  All calculations are valid regardless of the message frequency &nbsp; $f_{\rm N}$ if the attenuation factor of the upper sideband remains at &nbsp; $α_{\rm O} = 0.25$&nbsp;.
-*Damit erhält man auch für&nbsp; $f_{\rm N} = 4 \ \rm kHz$&nbsp; den gleichen Klirrfaktor&nbsp; $K\hspace{0.15cm}\underline { \approx 6.6 \%}$.
+*Thus, the same distortion factor &nbsp; $K\hspace{0.15cm}\underline { \approx 6.6 \%}$ is obtained for &nbsp; $f_{\rm N} = 4 \ \rm kHz$&nbsp;.
 {{ML-Fuß}}