Difference between revisions of "Theory of Stochastic Signals/Creation of Predefined ACF Properties"

Latest revision as of 20:55, 21 December 2022

ACF at the output of a non-recursive filter

We consider a non-recursive $M$–th order digital filter according to the following diagram.

$M$-th order non-recursive filter

The discrete-time input variable $〈\hspace{0.05cm}x_ν\hspace{0.05cm}〉$ is

mean–free $(m_x = 0)$,
Gaussian distributed (with standard deviation ⇒ "standard deviation" $σ_x)$, and
without memory ("white noise") ⇒ statistically independent samples.

This results in the following properties:

The discrete-time auto-correlation function $\rm (ACF)$ at the input is:

$$\varphi _x ( {k \cdot T_{\rm A} } ) = \left\{ {\begin{array}{*{20}c} {\sigma _x ^2 } & {\rm{for}\quad {\it k} = 0,} \\ 0 & {\rm{for}\quad {\it k} \ne 0.} \\\end{array}} \right.$$

The ACF of the discrete-time output sequence $〈\hspace{0.05cm}y_ν\hspace{0.05cm}〉$ is given as follows:

$$\varphi _y ( {k \cdot T_{\rm A} } ) = \sigma _x ^2 \cdot \sum\limits_{\mu = 0}^{M - k} {a_\mu \cdot a_{\mu + k } } \quad {\rm{for}}\quad {\it k} = 0, 1,\,\text{...}\,,\,{\it M}.$$

All ACF values with $k > M$ are zero, and all ACF values with $k < M$ are symmetric about $k = 0$:

$$\varphi _y ( { - k \cdot T_{\rm A} } ) = \varphi _y ( {k \cdot T_{\rm A} } ).$$

$\text{Example 1:}$ If discrete-time white noise with standard deviation $σ_x = 2$ is present at the input of a first-order non-recursive filter $($filter coefficients $a_0 = 0.6$, $a_1 = 0.8),$ the discrete ACF values of the output signal are (all other ACF values are zero):

ACF at the output of a first order filter

$$\varphi _y (0) = \sigma _x ^2 \cdot ( {a_0 ^2 + a_1 ^2 }) = 4,$$

$$\varphi _y ( { - T_{\rm A} } ) = \varphi _y ( {T_{\rm A} } ) = \sigma _x ^2 \cdot a_0 \cdot a_1 = 1.92.$$

The graphic can be interpreted as follows:

Because of $a_0^2 + a_1^2 = 1$, the output signal $y(t)$ has exactly the same variance $σ_y^2 = φ_y(0) = 0.4$ as the input signal: $σ_x^2 = φ_x(0)$.
Unlike the input sequence $〈\hspace{0.05cm}x_ν\hspace{0.05cm}〉$, the output sequence $〈\hspace{0.05cm}y_ν\hspace{0.05cm}〉$ has statistical bindings between adjacent samples.

Determining the coefficients

Now the following question is to be answered: How can the coefficients $a_0$, ... , $a_M$ of a $M$–th order non-recursive filter can be determined,

if the desired ACF values $φ_y(0)$, ... ,s $φ_y(M · T_{\rm A})$ are given and
outside the range from $-M · T_{\rm A}$ to $+M · T_{\rm A}$ all ACF values are to be zero.

For the standard deviation $σ_x = 1$, the following nonlinear system of equations is obtained, using $φ_k = φ_y(k · T_{\rm A})$ for simplicity of notation:

$$\begin{align*}\varphi _0 & = \sum\limits_{\mu = 0}^M {a_\mu^2 ,}\\ \varphi _1 & = \sum\limits_{\mu = 0}^{M - 1} {a_\mu \cdot a_{\mu + 1} ,} \\ & ... &\\ \varphi _{M - 1} & = a_0 \cdot a_{M - 1} + a_1 \cdot a_M , \\ \varphi _M & = a_0 \cdot a_M .\end{align*}$$

$\text{Conclusion:}$

Thus, for the $M + 1$ coefficients, one also obtains $M + 1$ independent equations.
By successive elimination of the coefficients $a_1$, ... , $a_M$, finally a nonlinear equation of higher order remains for $a_0$.

$\text{Example 2:}$ We consider the following constellation:

a recursive filter of first order ⇒ $M = 1$,
a discrete-time input sequence $〈\hspace{0.05cm}x_ν\hspace{0.05cm}〉$ with mean $m_x =$ 0 and standard deviation $σ_x = 1$,
desired ACF values of the sequence $〈\hspace{0.05cm}y_ν\hspace{0.05cm}〉$: $ φ_y(0) = φ_0 =0.58$, $φ_y(±T_{\rm A}) = φ_1 = 0.21$.

Thus, the above system of equations is:

$$\varphi _0 = a_0 ^2 + a_1 ^2 = 0.58,$$

$$\varphi _1 = a_0 \cdot a_1 = 0.21.$$

This leads to an equation of degree $4$,

$$a_0 ^2 + \left( { { {0.21} }/{ {a_0 } } } \right)^2 = 0.58\quad \Rightarrow \quad a_0 ^4 - 0.58 \cdot a_0 ^2 + 0.21^2 = 0.$$

A solution represents $a_0 = 0.7$. By inserting it into the second equation, we find $a_1 = 0.3$.

One recognizes from this example that already in the simplest case ⇒ $M = 1$ for $a_0$ a nonlinear determination equation of degree $4$ results.

Ambiguities in the determination of the coefficients

As the last example showed, with $M = 1$ the determination equation for $a_0$ is of degree $4$. At the same time, this means that there are also four sets of coefficients, all leading to the same ACF.

This is obvious for the following reasons:

The coefficients $a_0$ and $a_1$ can change sign simultaneously without changing the system of equations.
Replacing $a_0$ by $a_1$ and vice versa results in the same equation of determination.
This operation corresponds to a mirroring and shifting of the impulse response.

$\text{Example 3:}$ As shown in the "last section", the parameter set $a_0 = 0.7$, $a_1 = 0.3$ is suitable to generate the ACF values $φ_0 = 0.58$ and $φ_1 = 0.21$. The desired ACF of the output sequence is then in detailed notation:

Example of ACF calculation

$$\varphi_y(\tau) = 0.58 \cdot \delta(\tau) + 0.21 \cdot \delta(\tau - T_{\rm A}) + 0.21 \cdot \delta(\tau + T_{\rm A}) .$$

The same ACF is also obtained with the coefficients

$a_0 = - 0.7,\quad a_1 = -0.3,$
$a_0 = +0.3,\quad a_1 = +0.7,$
$a_0 = - 0.3,\quad a_1 = -0.7.$

These configurations are obtained by

simultaneously multiplying all coefficients by $-1$, and
swapping the numerical values of $a_0$ and $a_1$.

The diagram shows the respective impulse responses leading to the desired ACF.

Exercises for the chapter

Exercise 5.5: ACF-equivalent Filters

Exercise 5.5Z: ACF after 1st Order Filter

Exercise 5.6: Filter Dimensioning

Exercise 5.6Z: Filter Dimensioning again

@@ Line 1: / Line 1: @@
 {{Header
-|Untermenü=Filterung stochastischer Signale
+|Untermenü=Filtering of Stochastic Signals
 |Vorherige Seite=Digitale Filter
-|Nächste Seite=Matched-Filter
+|Nächste Seite=Matched Filter
 }}
-==AKF am Ausgang eines nichtrekursiven Filters==
+==ACF at the output of a non-recursive filter==
-Wir betrachten ein ''nichtrekursives Laufzeitfilter M-ter Ordnung'' gemäß der folgenden Grafik. Die zeitdiskrete Eingangsgröße $〈x_ν〉$ ist mittelwertfrei $(m_x =$ 0), gaußverteilt (mit Streuung $σ_x$) und statistisch unabhängig („Weißes Rauschen”).
+<br>
+We consider &nbsp; a non-recursive&nbsp; $M$&ndash;th order digital&nbsp; filter according to the following diagram.
+[[File:P_ID555__Sto_T_5_3_S1_neu.png |frame| $M$-th order non-recursive filter]]
+The discrete-time input variable&nbsp; $〈\hspace{0.05cm}x_ν\hspace{0.05cm}〉$&nbsp; is
+* mean&ndash;free&nbsp; $(m_x = 0)$,
+* Gaussian distributed&nbsp; (with&nbsp; standard deviation&nbsp; &rArr; &nbsp; "standard deviation"&nbsp; $σ_x)$,&nbsp; and
+* without memory&nbsp; ("white noise") &nbsp; &rArr; &nbsp; statistically independent samples.
-:::[[File:P_ID555__Sto_T_5_3_S1_neu.png | Nichtrekursives Filter M-ter Ordnung]]
+This results in the following properties:
+*The discrete-time auto-correlation function&nbsp; $\rm (ACF)$&nbsp; at the input is:
+:$$\varphi _x ( {k \cdot T_{\rm A} } ) = \left\{ {\begin{array}{*{20}c}   {\sigma _x ^2 } & {\rm{for}\quad {\it k} = 0,}  \\   0 & {\rm{for}\quad {\it k} \ne 0.}  \\\end{array}} \right.$$
+*The ACF of the discrete-time output sequence&nbsp; $〈\hspace{0.05cm}y_ν\hspace{0.05cm}〉$&nbsp; is given as follows:
+:$$\varphi _y ( {k \cdot T_{\rm A} } ) = \sigma _x ^2  \cdot \sum\limits_{\mu  = 0}^{M - k} {a_\mu   \cdot a_{\mu  + k } } \quad {\rm{for}}\quad {\it k} = 0, 1,\,\text{...}\,,\,{\it M}.$$
+*All ACF values with&nbsp; $k > M$&nbsp; are zero,&nbsp; and all ACF values with&nbsp; $k < M$&nbsp; are symmetric about&nbsp; $k = 0$:
+:$$\varphi _y ( { - k \cdot T_{\rm A} } ) = \varphi _y ( {k \cdot T_{\rm A} } ).$$
+{{GraueBox|TEXT=
+$\text{Example 1:}$&nbsp; If discrete-time white noise with standard deviation&nbsp; $σ_x = 2$&nbsp; is present at the input of a first-order non-recursive filter&nbsp; $($filter coefficients&nbsp; $a_0 = 0.6$,&nbsp; $a_1 = 0.8),$&nbsp; the discrete ACF values of the output signal are (all other ACF values are zero):
-*Somit gilt für die zeitdiskrete Autokorrelationsfunktion am Eingang:
+[[File:P_ID597__Sto_T_5_3_S1_b_neu.png |frame| ACF at the output of a first order filter|right]]
-$$\varphi _x ( {k \cdot T_{\rm A} } ) = \left\{ {\begin{array}{*{20}c}   {\sigma _x ^2 } & {\rm{f\ddot{u}r}\quad {\it k} = 0,}  \\   0 & {\rm{f\ddot{u}r}\quad {\it k} \ne 0.}  \\\end{array}} \right.$$
+:$$\varphi _y (0) = \sigma _x ^2  \cdot ( {a_0 ^2  + a_1 ^2 }) = 4,$$
-*Die AKF der zeitdiskreten Ausgangsfolge $〈y_ν〉$ lautet:
+:$$\varphi _y ( { - T_{\rm A} } ) = \varphi _y ( {T_{\rm A} } ) = \sigma _x ^2  \cdot a_0  \cdot a_1  = 1.92.$$
-$$\varphi _y ( {k \cdot T_{\rm A} } ) = \sigma _x ^2  \cdot \sum\limits_{\mu  = 0}^{M - k} {a_\mu   \cdot a_{\mu  + k } } \quad {\rm{f\ddot{u}r}}\quad {\it k} = 0, 1,\,...\,,\,{\it M}.$$
-*Alle AKF–Werte mit $k > M$ sind 0, und alle AKF–Werte mit $k < M$ sind symmetrisch um 0:
-$$\varphi _y ( { - k \cdot T_{\rm A} } ) = \varphi _y ( {k \cdot T_{\rm A} } ).$$
+The graphic can be interpreted as follows:
+*Because of&nbsp; $a_0^2 + a_1^2 = 1$,&nbsp; the output signal&nbsp; $y(t)$&nbsp; has exactly the same variance&nbsp; $σ_y^2 = φ_y(0) = 0.4$&nbsp; as the input signal: &nbsp;  $σ_x^2 = φ_x(0)$.
+*Unlike the input sequence&nbsp; $〈\hspace{0.05cm}x_ν\hspace{0.05cm}〉$,&nbsp; the output sequence&nbsp; $〈\hspace{0.05cm}y_ν\hspace{0.05cm}〉$&nbsp; has statistical bindings between adjacent samples. }}
-{{Beispiel}}
+==Determining the coefficients==
-Liegt am Eingang eines nichtrekursiven Filters erster Ordnung (Filterkoeffizienten $a_0 =$ 0.6, $a_1 =$ 0.8) zeitdiskretes weißes Rauschen mit der Streuung $σ_x =$ 2 an, so lauten die diskreten AKF-Werte des Ausgangssignals (alle anderen AKF-Werte sind 0):
+<br>
-$$\varphi _y (0) = \sigma _x ^2  \cdot ( {a_0 ^2  + a_1 ^2 }) = 4,\hspace{0.8cm}
+Now the following question is to be answered: &nbsp; How can the coefficients&nbsp; $a_0$, ... , $a_M$&nbsp; of a&nbsp; $M$&ndash;th order non-recursive filter can be determined,
-\varphi _y ( { - T_{\rm A} } ) = \varphi _y ( {T_{\rm A} } ) = \sigma _x ^2  \cdot a_0  \cdot a_1  = 1.92.$$
+* if the desired ACF values&nbsp; $φ_y(0)$, ... ,s&nbsp; $φ_y(M · T_{\rm A})$&nbsp; are given&nbsp; and
+* outside the range from&nbsp;  $-M · T_{\rm A}$&nbsp; to&nbsp; $+M · T_{\rm A}$&nbsp; all ACF values are to be zero.
-:::[[File:P_ID597__Sto_T_5_3_S1_b_neu.png | AKF am Ausgang eines Filters erster Ordnung]]
+For the standard deviation&nbsp; $σ_x = 1$,&nbsp; the following nonlinear system of equations is obtained,&nbsp; using&nbsp; $φ_k = φ_y(k · T_{\rm A})$&nbsp; for simplicity of notation:
+:$$\begin{align*}\varphi _0 & = \sum\limits_{\mu  = 0}^M {a_\mu^2  ,}\\ \varphi _1 &  = \sum\limits_{\mu  = 0}^{M - 1} {a_\mu   \cdot a_{\mu  + 1} ,}  \\ & ... &\\  \varphi _{M - 1} & = a_0  \cdot a_{M - 1}  + a_1  \cdot a_M ,  \\ \varphi _M  & =  a_0  \cdot a_M .\end{align*}$$
+{{BlaueBox|TEXT=
+$\text{Conclusion:}$&nbsp;
+*Thus,&nbsp; for the&nbsp; $M + 1$&nbsp; coefficients,&nbsp; one also obtains&nbsp; $M + 1$&nbsp; independent equations.
+*By successive elimination of the coefficients&nbsp; $a_1$, ... ,&nbsp; $a_M$,&nbsp; finally a nonlinear equation of higher order remains for&nbsp; $a_0$.}}
-Die Grafik kann wie fiolgt interpretiert werden:
-*Wegen $a_0^2 + a_1^2 =$ 1 besitzt das Ausgangssignal $y(t)$ genau die gleiche Varianz $σ_y^2 = φ_y(0)$ wie das Eingangssignal: $σ_x^2 = φ_x(0) =$ 4.
-*Im Gegensatz zur Eingangsfolge $〈x_ν〉$ gibt es bei der Folge $〈y_ν〉$ am Filterausgang statistische Bindungen zwischen benachbarten Abtastwerten.
+{{GraueBox|TEXT=
+$\text{Example 2:}$&nbsp; We consider the following constellation:
+#a recursive filter of first order &nbsp; ⇒  &nbsp; $M = 1$,
+#a discrete-time input sequence&nbsp; $〈\hspace{0.05cm}x_ν\hspace{0.05cm}〉$&nbsp; with mean&nbsp; $m_x =$ 0 &nbsp; and&nbsp; standard deviation&nbsp; $σ_x = 1$,
+#desired ACF values of the sequence&nbsp; $〈\hspace{0.05cm}y_ν\hspace{0.05cm}〉$: &nbsp; $ φ_y(0) = φ_0 =0.58$, &nbsp;  $φ_y(±T_{\rm A}) = φ_1 = 0.21$.
-{{end}}
-==Koeffizientenbestimmung (1)==
+*Thus,&nbsp; the above system of equations is:
-Nun soll die Frage geklärt werden, wie die Koeffizienten $a_0, ... , a_M$ eines nichtrekursiven Filters $M$-ter Ordnung ermittelt werden können, wenn die gewünschten AKF-Werte $φ_y(0), ... , φ_y(M · T_{\rm A})$ gegeben sind. Außerhalb des Bereiches $–M · T_{\rm A} ... M · T_{\rm A}$ sollen alle AKF-Werte gleich 0 sein.
+:$$\varphi _0  = a_0 ^2  + a_1 ^2  = 0.58,$$
+:$$\varphi _1  = a_0  \cdot a_1  = 0.21.$$
+*This leads to an equation of degree&nbsp; $4$,&nbsp;
+:$$a_0 ^2  + \left( { { {0.21} }/{ {a_0 } } } \right)^2  = 0.58\quad  \Rightarrow \quad a_0 ^4  - 0.58 \cdot a_0 ^2  + 0.21^2  = 0.$$
+*A solution represents&nbsp; $a_0 = 0.7$.&nbsp; &nbsp; By inserting it into the second equation, we find&nbsp; $a_1 = 0.3$.
-Für $σ_x =$ 1 ergibt sich das folgende ''nichtlineare Gleichungssystem'', wobei zur Vereinfachung der Schreibweise $φ_k = φ_y(k · T_{\rm A})$ verwendet wird:
-$$\begin{align*}\varphi _0 & = \sum\limits_{\mu  = 0}^M {a_\mu^2  ,}\\ \varphi _1 &  = \sum\limits_{\mu  = 0}^{M - 1} {a_\mu   \cdot a_{\mu  + 1} ,} \\ & . & \\ & . &\\ & . &\\ \varphi _{M - 1} & = a_0  \cdot a_{M - 1}  + a_1  \cdot a_M , \\ \varphi _M  & =  a_0  \cdot a_M .\end{align*}$$
-Man erhält somit für die $M +$ 1 Koeffizienten auch $M +$ 1 unabhängige Gleichungen. Durch sukzessives Eliminieren der Koeffizienten $a_1, ... , a_M$ bleibt für $a_0$ eine nichtlineare Gleichung höherer Ordnung übrig.
+One recognizes from this example that already in the simplest case &nbsp;  ⇒ &nbsp;  $M = 1$&nbsp; for&nbsp; $a_0$&nbsp; a nonlinear determination equation of degree&nbsp; $4$&nbsp; results.}}
-{{Beispiel}}
+==Ambiguities in the determination of the coefficients==
-Wir betrachten folgende Konstellation:
+<br>
-*ein rekursives Filter erster Ordnung  ⇒  $M =$ 1,
+As the last example showed,&nbsp; with&nbsp; $M = 1$&nbsp; the determination equation for&nbsp; $a_0$&nbsp; is of degree&nbsp; $4$.&nbsp; At the same time,&nbsp; this means that there are also four sets of coefficients,&nbsp; all leading to the same ACF.
-*eine zeitdiskrete Eingangsfolge $〈x_ν〉$ mit Mittelwert $m_x =$ 0 und Streuung $σ_x =$ 1,
-*gewünschte AKF-Werte der Folge $〈y_ν〉: φ_y(0) = φ_0 =$ 0.58 und $φ_y(±T_{\rm A}) = φ_1 =$ 0.21.
+This is obvious for the following reasons:
+*The coefficients&nbsp; $a_0$&nbsp; and&nbsp; $a_1$&nbsp; can change sign simultaneously without changing the system of equations.
+*Replacing&nbsp; $a_0$ &nbsp; by&nbsp; $a_1$ &nbsp; and vice versa results in the same equation of determination.
+*This operation corresponds to a mirroring and shifting of the impulse response.
-Damit lautet das obige Gleichungssystem:
-$$\varphi _0  = a_0 ^2  + a_1 ^2  = 0.58,$$
-$$\varphi _1  = a_0  \cdot a_1  = 0.21.$$
-Dies führt zu einer Gleichung vom Grad 4, nämlich
-$$a_0 ^2  + \left( { { {0.21} }/{ {a_0 } } } \right)^2  = 0.58\quad  \Rightarrow \quad a_0 ^4  - 0.58 \cdot a_0 ^2  + 0.21^2  = 0.$$
-Eine Lösung stellt $a_0 =$ 0.7 dar. Durch Einsetzen in die zweite Gleichung findet man $a_1 =$ 0.3.
-{{end}}
+{{GraueBox|TEXT=
+$\text{Example 3:}$&nbsp; As shown in the&nbsp; [[Theory_of_Stochastic_Signals/Creation_of_Predefined_ACF_Properties#Ambiguities_in_the_determination_of_the_coefficients|"last section"]],&nbsp; the parameter set&nbsp;$a_0 = 0.7$, &nbsp;$a_1 = 0.3$&nbsp; is suitable to generate the ACF values&nbsp;$φ_0 = 0.58$&nbsp; and &nbsp;$φ_1 = 0.21$.&nbsp; The desired ACF of the output sequence is then in detailed notation:
+[[File:P_ID557__Sto_T_5_3_S2_b_neu_100.png |frame| Example of ACF calculation|right]]
+:$$\varphi_y(\tau) = 0.58 \cdot \delta(\tau) + 0.21 \cdot \delta(\tau - T_{\rm A})
++ 0.21 \cdot \delta(\tau + T_{\rm A}) .$$
-Man erkennt aus diesem Beispiel, dass sich schon im einfachsten Fall  ⇒  $M =$ 1 eine nichtlineare Bestimmungsgleichung für $a_0$ vom Grad 4 ergibt.
+The same ACF is also obtained with the coefficients
+*$a_0 = - 0.7,\quad a_1  = -0.3,$
+*$a_0  = +0.3,\quad a_1  = +0.7,$
+*$a_0  =  - 0.3,\quad a_1 = -0.7.$
-==Koeffizientenbestimmung (2)==
-Wie das letzte Beispiel gezeigt hat, ist mit $M =$ 1 die Bestimmungsgleichung für $a_0$ vom Grad 4. Dies bedeutet gleichzeitig, dass es auch vier Koeffizientensätze gibt, die alle zur gleichen AKF führen. Dies ist aus folgenden Gründen einsichtig:
-*Die Koeffizienten $a_0$ und $a_1$ können gleichzeitig ihr Vorzeichen ändern, ohne dass dadurch das Gleichungssystem verändert wird.
-*Ersetzt man $a_0$ durch $a_1$ und umgekehrt, so ergibt sich die gleiche Bestimmungsgleichung. Diese Operation entspricht einer Spiegelung und Verschiebung der Impulsantwort.
+These configurations are obtained by
+*simultaneously multiplying all coefficients by&nbsp; $-1$,&nbsp; and
+*swapping the numerical values of&nbsp; $a_0$&nbsp; and&nbsp; $a_1$.
-{{Beispiel}}
+The diagram shows the respective impulse responses leading to the desired ACF.}}
-Wie im letzten Abschnitt gezeigt wurde, ist der Parametersatz $a_0 =$ 0.7, $a_1 =$ 0.3 geeignet, die AKF-Werte $φ_0 =$ 0.58 und $φ_1 =$ 0.21 zu generieren. Zur gleichen AKF kommt man auch mit den Koeffizientenpaaren
-$$a_0 = - 0.7,\quad a_1  = -0.3,\\a_0  = \;\;\,0.3,\quad a_1  = \hspace{0.33cm}0.7,\\a_0  =  - 0.3,\quad a_1 = -0.7.$$
-Das folgende Bild zeigt die entsprechenden Impulsantworten, die zur gewünschten AKF führen:
-$$\varphi_y(\tau) = 0.58 \cdot \delta(\tau) + 0.21 \cdot \delta(\tau - T_{\rm A})
-+ 0.21 \cdot \delta(\tau + T_{\rm A}) .$$
+==Exercises for the chapter==
+<br>
+[[Aufgaben:Exercise_5.5:_ACF-Equivalent_Filters|Exercise 5.5: ACF-equivalent Filters]]
-:::[[File:P_ID557__Sto_T_5_3_S2_b_neu_100.png | Beispiel zur AKF-Berechnung]]
+[[Aufgaben:Exercise_5.5Z:_ACF_after_1st_Order_Filter|Exercise 5.5Z: ACF after 1st Order Filter]]
+[[Aufgaben:Exercise_5.6:_Filter_Dimensioning|Exercise 5.6: Filter Dimensioning]]
-Diese Konfigurationen ergeben sich durch gleichzeitiges Multiplizieren aller Koeffizienten mit –1 sowie durch Vertauschen der Zahlenwerte von $a_0$ und $a_1$.
+[[Aufgaben:Aufgabe_5.6Z:_Nochmals_Filterdimensionierung|Exercise 5.6Z: Filter Dimensioning again]]
-{{end}}
 {{Display}}