Difference between revisions of "Aufgaben:Exercise 3.1: Causality Considerations"

Revision as of 08:59, 24 September 2021

Two two-port networks

The graph shows above the two-port network with the transfer function

$$H_1(f) = \frac{{\rm j}\cdot f/f_{\rm G}}{1+{\rm j}\cdot f/f_{\rm G}} \hspace{0.05cm},$$

where $f_{\rm G}$ represents the 3dB cut-off frequency:

$$f_{\rm G} = \frac{R}{2 \pi \cdot L} \hspace{0.05cm}.$$

By cascading $n$ two-port networks $H_1(f)$ built the same way, the transfer function

$$H_n(f) = \big [H_1(f)\big ]^n =\frac{\big [{\rm j}\cdot f/f_{\rm G}\big ]^n}{\big [1+{\rm j}\cdot f/f_{\rm G}\big ]^n} \hspace{0.05cm}$$ is obtained.

Here, a suitable resistor decoupling is presumed, but this is not important for solving this exercise.
The lower graph shows for example the realization of the transfer function $H_2(f)$.

In this exercise, such a two-port network is considered with respect to its causality properties.

For any causal system, the real and imaginary parts of the spectral function $H(f)$ satisfy the Hilbert transformation, which is expressed by the following abbreviation:

$${\rm Im} \left\{ H(f) \right \} \quad \bullet\!\!-\!\!\!-\!\!\!-\!\!\hspace{-0.05cm}\rightarrow\quad {\rm Re} \left\{ H(f) \right \}\hspace{0.05cm}.$$

Since the Hilbert transformation provides important information not only for transfer functions but also for time signals, the correspondence is often expressed by the general variable $x$ , which is to be interpreted - depending on the application - as normalized frequency or normalized time.

Please note:

The exercise belongs to the chapter Conclusions from the Allocation Theorem.
Reference is also made to the theory pages Hilbert transformation and Partial fraction decomposition.

Questions

	$H_1(f)$ describes a low-pass filter.
	$H_1(f)$ describes a high-pass filter.

	Yes.
	No.

${\rm Re}\big[H_2(f = f_{\rm G})\big] \ = \ $

${\rm Im}\big[H_2(f = f_{\rm G})\big] \ = \ $

	$H_2(f)$ describes a causal system.
	The expressions $(x^4 - x^2)/(x^4 +2 x^2 + 1)$ and $2x^3/(x^4 +2 x^2 + 1)$ are a Hilbert pair.
	The causality condition is not satisfied for $n > 2$ .

Solution

(1) Proposed solution 2 is cocrrect:

The given transfer function can be computed according to the voltage divider principle. The following holds:

$$H_1(f = 0) = 0, \hspace{0.2cm}H_1(f \rightarrow \infty) = 1$$

This is a high-pass filter.
For very low frequencies, the inductivity $L$ constitutes a short circuit.

(2) Yes is cocrrect:

Every real network is causal. The impulse response $h(t)$ is equal to the output signal $y(t)$ if at time $t= 0$ an extremely short impulse – a so-called Dirac impulse – is applied to the input.
Then, a signal of course cannot occur at the output already for times $t< 0$ for causality reasons:

$$y(t) = h(t) = 0 \hspace{0.2cm}{\rm{f\ddot{u}r}} \hspace{0.2cm} t<0 \hspace{0.05cm}.$$

Formally, this can be shown as follows: The high-pass–transfer function $H_1(f)$ can be rearranged as follows:

$$H_1(f) = \frac{{\rm j}\cdot f/f_{\rm G}}{1+{\rm j}\cdot f/f_{\rm G}} = 1- \frac{1}{1+{\rm j}\cdot f/f_{\rm G}} \hspace{0.05cm}.$$

The second transfer function describes the low-pass function equivalent to $H_1(f)$, which results in the exponential function in the time domain.
The "$1$" becomes a Dirac function. Considering $T = 2\pi \cdot f_{\rm G}$ the following thus holds for $t \ge 0$:

$$h_1(t) = \delta(t) - {1}/{T} \cdot {\rm e}^{-t/T} \hspace{0.05cm}.$$

In contrast, $h_1(t)= 0$ holds for $t< 0$ , which would prove causality.

(3) Die Hintereinanderschaltung zweier Hochpässe führt zu folgender Übertragungsfunktion:

$$H_2(f) = \big [H_1(f)\big ]^2 =\frac{\big [{\rm j}\cdot f/f_{\rm G}\big ]^2}{\big [1+{\rm j}\cdot f/f_{\rm G}\big ]^2} =\frac{\big [{\rm j}\cdot f/f_{\rm G}\big ]^2 \cdot \big [(1-{\rm j}\cdot f/f_{\rm G})\big ]^2} {\big [(1+{\rm j}\cdot f/f_{\rm G}) \cdot (1-{\rm j}\cdot f/f_{\rm G})\big ]^2}= \frac{(f/f_{\rm G})^4 - (f/f_{\rm G})^2 +{\rm j}\cdot 2 \cdot (f/f_{\rm G})^3)} {\big [1+(f/f_{\rm G})^2 \big ]^2}\hspace{0.05cm}.$$

Mit $f = f_{\rm G}$ folgt daraus:

$$H_2(f = f_{\rm G}) = \frac{1 - 1 +{\rm j}\cdot 2} {4}= {\rm j} /{2} \hspace{0.5cm}\Rightarrow \hspace{0.5cm}{\rm Re} \left\{ H_2(f = f_{\rm G}) \right \} \hspace{0.15cm}\underline{ = 0}, \hspace{0.4cm} {\rm Im} \left\{ H_2(f = f_{\rm G}) \right \} \hspace{0.15cm}\underline{ = 0.5}\hspace{0.05cm}.$$

(4) Richtig sind die beiden ersten Lösungsvorschläge:

Da für $t < 0$ die Impulsantwort $h_1(t) = 0$ ist, erfüllt auch die Faltungsoperation $h_2(t) = h_1(t) \star h_1(t)$ die Kausalitätsbedingung. Ebenso ergibt die $n$–fache Faltung eine kausale Impulsantwort: $h_n(t) = 0 \hspace{0.2cm}{\rm{f\ddot{u}r}} \hspace{0.2cm} t<0 \hspace{0.05cm}.$
Bei kausaler Impulsantwort $h_2(t)$ hängen aber der Real– und der Imaginärteil der Spektralfunktion $H_2(f)$ über die Hilbert–Transformation zusammen. Mit der Abkürzung $x = f/f_{\rm G}$ und dem Ergebnis der Teilaufgabe (3) gilt somit:

$$\frac{x^4- x^2}{x^4+2 x^2+1} \quad \bullet\!\!-\!\!\!-\!\!\!-\!\!\hspace{-0.05cm}\rightarrow\quad \frac{2x^3}{x^4+2 x^2+1}\hspace{0.05cm}.$$

@@ Line 75: / Line 75: @@
 ===Solution===
 {{ML-Kopf}}
-'''(1)'''&nbsp; Richtig ist der <u>Lösungsvorschlag 2</u>:
+'''(1)'''&nbsp; <u>Proposed solution 2</u> is cocrrect:
-*Die angegebene Übertragungsfunktion kann man nach dem Spannungsteilerprinzip berechnen. &nbsp; Es gilt:
+*The given transfer function can be computed according to the voltage divider principle. &nbsp; The following holds:
 :$$H_1(f = 0) = 0, \hspace{0.2cm}H_1(f \rightarrow \infty) = 1$$
-*Es handelt sich um einen Hochpass.
+*This is a high-pass filter.
-*Für sehr niedrige Frequenzen stellt die Induktivität&nbsp; $L$&nbsp; einen Kurzschluss dar.
+*For very low frequencies, the inductivity&nbsp; $L$&nbsp; constitutes a short circuit.
-'''(2)'''&nbsp; Richtig ist <u>Ja</u>:
+'''(2)'''&nbsp; <u>Yes</u> is cocrrect:
-*Jedes reale Netzwerk ist kausal.&nbsp; Die Impulsantwort&nbsp; $h(t)$&nbsp; ist gleich dem Ausgangssignal&nbsp; $y(t)$, wenn zum Zeitpunkt&nbsp; $t= 0$&nbsp; am Eingang ein extrem kurzfristiger Impuls &ndash; ein so genannter Diracimpuls &ndash; angelegt wird.
+*Every real network is causal.&nbsp; The impulse response&nbsp; $h(t)$&nbsp; is equal to the output signal&nbsp; $y(t)$ if at time&nbsp; $t= 0$&nbsp; an extremely short impulse &ndash; a so-called Dirac impulse &ndash; is applied to the input.
-*Aus Kausalitätsgründen kann dann natürlich am Ausgang nicht schon für Zeiten&nbsp; $t< 0$&nbsp; ein Signal auftreten:
+*Then, a signal of course cannot occur at the output already for times&nbsp; $t< 0$&nbsp; for causality reasons:
 :$$y(t) = h(t) = 0 \hspace{0.2cm}{\rm{f\ddot{u}r}} \hspace{0.2cm}
   t<0 \hspace{0.05cm}.$$
-*Formal lässt sich dies folgendermaßen zeigen: &nbsp; Die Hochpass&ndash;Übertragungsfunktion&nbsp; $H_1(f)$&nbsp; kann wie folgt umgeformt werden:
+*Formally, this can be shown as follows: &nbsp; The high-pass&ndash;transfer function&nbsp; $H_1(f)$&nbsp; can be rearranged as follows:
 :$$H_1(f) = \frac{{\rm j}\cdot f/f_{\rm G}}{1+{\rm j}\cdot f/f_{\rm G}}
   = 1- \frac{1}{1+{\rm j}\cdot f/f_{\rm G}}
   \hspace{0.05cm}.$$
-*Die zweite Übertragungsfunktion beschreibt die zu&nbsp; $H_1(f)$&nbsp; äquivalente Tiefpassfunktion, die im Zeitbereich zur Exponentialfunktion führt.
+*The second transfer function describes the low-pass function equivalent to&nbsp; $H_1(f)$,&nbsp; which results in the exponential function in the time domain.
-*Die "$1$" wird zu einer Diracfunktion.&nbsp; Mit&nbsp; $T = 2\pi \cdot f_{\rm G}$&nbsp; gilt somit für&nbsp; $t \ge 0$:
+*The "$1$" becomes a Dirac function.&nbsp; Considering&nbsp; $T = 2\pi \cdot f_{\rm G}$&nbsp; the following thus holds for&nbsp; $t \ge 0$:
 :$$h_1(t) = \delta(t) - {1}/{T} \cdot {\rm e}^{-t/T} \hspace{0.05cm}.$$
-*Für&nbsp; $t< 0$&nbsp; gilt dagegen&nbsp; $h_1(t)= 0$, womit die Kausalität nachgewiesen wäre.
+*In contrast, &nbsp; $h_1(t)= 0$ holds for&nbsp; $t< 0$&nbsp;, which would prove causality.