Difference between revisions of "Aufgaben:Exercise 4.10Z: Correlation Duration"

Latest revision as of 18:52, 20 March 2022

Pattern signals of ergodic processes

The graphic shows pattern signals of two random processes $\{x_i(t)\}$ and $\{y_i(t)\}$ with equal power

$$P_x = P_y = 5\hspace{0.05 cm} \rm mW.$$

Assuming here the resistance $R = 50\hspace{0.05 cm}\rm \Omega$.

The random process $\{x_i(t)\}$

is zero mean $(m_x = 0)$,
has the Gaussian ACF $\varphi_x (\tau) = \varphi_x (\tau = 0) \cdot {\rm e}^{- \pi \hspace{0.03cm} \cdot \hspace{0.03cm}(\tau / {\rm \nabla} \tau_x)^2},$ and
exhibits the equivalent ACF duration $\nabla \tau_x = 5\hspace{0.05 cm}\rm µ s $ .

As can be seen from the diagram below, the random process $\{y_i(t)\}$ has much stronger internal statistical bindings than the random process $\{x_i(t)\}$. Or, to put it another way:

The random process $\{y_i(t)\}$ is lower frequency than $\{x_i(t)\}$.
The equivalent ACF duration is $\nabla \tau_y = 10 \hspace{0.05 cm}\rm µ s $.

From the sketch it can also be seen that $\{y_i(t)\}$ in contrast to $\{x_i(t)\}$ is not DC free. The DC signal component is rather $m_y = -0.3 \hspace{0.05 cm}\rm V$.

Hint:

The exercise belongs to the chapter Auto-Correlation Function.
Reference is made in particular to the section Interpretation of the auto-correlation function.

Questions

$\sigma_x \ = \ $

$\ \rm V$

$\varphi_x(\tau = 2\hspace{0.05 cm}{\rm µ s}) \ = \ $

$\ \rm mW$

$\varphi_x(\tau = 5\hspace{0.05 cm}{\rm µ s}) \ = \ $

$\ \rm mW$

$T_{\rm K} \ = \ $

$\ \rm µ s$

$\sigma_y \ = \ $

$\ \rm V$

$\varphi_y(\tau = 10\hspace{0.05 cm}{\rm µ s}) \ = \ $

$\ \rm mW$

Solution

(1) The second moment results to $m_{2x} = R \cdot P_x = 50 \hspace{0.05 cm}{\rm \Omega}\cdot 5 \hspace{0.05 cm}{\rm mW}= 0.25 \hspace{0.05 cm}{\rm V}^2.$

From this follows the standard deviation $\sigma_x\hspace{0.15 cm}\underline{= 0.5\hspace{0.05 cm}{\rm V}}$.

(2) Because of $P_x = \varphi_x (\tau = 0)$ holds for the ACF in general:

$$\varphi_x (\tau) = 5 \hspace{0.1cm} {\rm mW} \cdot {\rm e}^{- \pi \hspace{0.03cm} \cdot \hspace{0.03cm}(\tau / {\rm \nabla} \tau_x)^2}.$$

From this we obtain:

$$\varphi_x (\tau = {\rm 2\hspace{0.1cm} µ s}) = 5 \hspace{0.1cm} {\rm mW} \cdot {\rm e}^{- {\rm 0.16 }\pi } \hspace{0.15cm}\underline{= 3.025 \hspace{0.1cm} \rm mW},$$

$$\varphi_x (\tau = {\rm 5\hspace{0.1cm} \rm µ s}) = 5 \hspace{0.1cm} {\rm mW} \cdot {\rm e}^{- \pi } \hspace{0.15cm}\underline{= 0.216 \hspace{0.1cm} \rm mW}.$$

Two times Gaussian ACF

(3) Here the following determination equation holds:

$${\rm e}^{- \pi \hspace{0.03cm} \cdot \hspace{0.03cm}(T_{\rm K} / {\rm \nabla} \tau_x)^2} \stackrel{!}{=} {\rm 0.5} \hspace{0.5cm}\Rightarrow\hspace{0.5cm} (T_{\rm K} / {\rm \nabla} \tau_x)^2 = \sqrt{{ \ln(2)}/{\pi}}\hspace{0.05cm}.$$

From this follows $T_{\rm K}\hspace{0.15 cm}\underline{= 2.35\hspace{0.05 cm}{\rm µ s}}$.
With another ACF form, a different ratio is obtained for $T_{\rm K} / {\rm \nabla} \tau_x$.

(4) Because of $P_x = P_y$ the second order moments of $x$ and $y$ are equal $0.25\hspace{0.05 cm}\rm V^2$.

Taking into account the mean value $m_y = -0.3 \hspace{0.05 cm}\rm V$ holds:

$$m_y^2 + \sigma_y^2 = \rm 0.25 \hspace{0.05 cm} V^2.$$

From this follows:

$$\sigma_y\hspace{0.15 cm}\underline{= 0.4\hspace{0.05 cm}{\rm V}}.$$

(5) In terms of unit resistance $ R = 1 \hspace{0.05 cm}{\rm \Omega}$ the ACF of the process $\{y_i(t)\}$ is:

$$\varphi_y (\tau) = m_y^2 + \sigma_y^2 \cdot {\rm e}^{- \pi \hspace{0.03cm} \cdot \hspace{0.03cm}(\tau / {\rm \nabla} \tau_y)^2}.$$

On the right you can see the ACF curve. Related to the resistor $ R = 50 \hspace{0.05 cm}{\rm \Omega}$ results in the following ACF values:

$$\varphi_y (\tau = 0) = 5 \hspace{0.1cm} {\rm mW} , \hspace{0.5cm} \varphi_y (\tau \rightarrow \infty) = 1.8\hspace{0.1cm} {\rm mW} .$$

From this follows:

$$\varphi_y(\tau) = 1.8 \hspace{0.1cm} {\rm mW} + 3.2 \hspace{0.1cm} {\rm mW} \cdot {\rm e}^{- \pi \hspace{0.03cm} \cdot \hspace{0.03cm}(\tau / {\rm \nabla} \tau_y)^2} \hspace{0.3cm }\Rightarrow \hspace{0.3cm }\varphi_y(\tau = 10\hspace{0.05 cm}{\rm µ s}) \hspace{0.15 cm}\underline{=1.938\hspace{0.05 cm}\rm mW}.$$

With positive mean $m_y$ $($having the same magnitude$)$, there would be no change in the ACF, since $m_y$ is squared in the ACF equation.

@@ Line 3: / Line 3: @@
 }}
-[[File:P_ID393__Sto_Z_4_10.png|right|frame|Sample functions of ergodic processes]]
+[[File:P_ID393__Sto_Z_4_10.png|right|frame|Pattern signals of ergodic processes]]
 The graphic shows pattern signals of two random processes&nbsp; $\{x_i(t)\}$&nbsp; and&nbsp; $\{y_i(t)\}$&nbsp; with equal power&nbsp;
 :$$P_x = P_y = 5\hspace{0.05 cm} \rm mW.$$
@@ Line 71: / Line 71: @@
 ===Solution===
 {{ML-Kopf}}
-'''(1)'''&nbsp; The quadratic mean results to&nbsp; $m_{2x} = R \cdot P_x = 50 \hspace{0.05 cm}{\rm \Omega}\cdot 5 \hspace{0.05 cm}{\rm mW}= 0.25 \hspace{0.05 cm}{\rm V}^2.$
+'''(1)'''&nbsp; The second moment results to&nbsp; $m_{2x} = R \cdot P_x = 50 \hspace{0.05 cm}{\rm \Omega}\cdot 5 \hspace{0.05 cm}{\rm mW}= 0.25 \hspace{0.05 cm}{\rm V}^2.$
 *From this follows the standard deviation&nbsp; $\sigma_x\hspace{0.15 cm}\underline{= 0.5\hspace{0.05 cm}{\rm V}}$.
-'''(2)'''&nbsp; Because&nbsp; $P_x = \varphi_x (\tau = 0)$&nbsp; holds for the ACF in general:
+'''(2)'''&nbsp; Because of&nbsp; $P_x = \varphi_x (\tau = 0)$&nbsp; holds for the ACF in general:
 :$$\varphi_x (\tau) = 5 \hspace{0.1cm} {\rm mW} \cdot {\rm e}^{- \pi \hspace{0.03cm} \cdot \hspace{0.03cm}(\tau / {\rm \nabla} \tau_x)^2}.$$
 *From this we obtain:
@@ Line 89: / Line 89: @@
 *From this follows&nbsp; $T_{\rm K}\hspace{0.15 cm}\underline{= 2.35\hspace{0.05 cm}{\rm &micro; s}}$.
-*With other ACF form, a different ratio is obtained for&nbsp; $T_{\rm K} / {\rm \nabla} \tau_x$.
+*With another ACF form,&nbsp; a different ratio is obtained for&nbsp; $T_{\rm K} / {\rm \nabla} \tau_x$.
-'''(4)'''&nbsp; Because&nbsp; $P_x = P_y$&nbsp; the root mean square values of&nbsp; $x$&nbsp; and&nbsp; $y$&nbsp; are equal, respectively&nbsp; $0.25\hspace{0.05 cm}\rm V^2$.
+'''(4)'''&nbsp; Because of&nbsp; $P_x = P_y$&nbsp; the second order moments of&nbsp; $x$&nbsp; and&nbsp; $y$&nbsp; are equal &nbsp; $0.25\hspace{0.05 cm}\rm V^2$.
 *Taking into account the mean value&nbsp; $m_y = -0.3 \hspace{0.05 cm}\rm V$&nbsp; holds:
 :$$m_y^2 + \sigma_y^2 = \rm 0.25 \hspace{0.05 cm} V^2.$$
@@ Line 102: / Line 102: @@
-'''(5)'''&nbsp; In terms of unit resistance&nbsp; $ R = 1 \hspace{0.05 cm}{\rm \Omega}$&nbsp; the ASF of the process&nbsp; $\{y_i(t)\}$ is:
+'''(5)'''&nbsp; In terms of unit resistance&nbsp; $ R = 1 \hspace{0.05 cm}{\rm \Omega}$&nbsp; the ACF of the process&nbsp; $\{y_i(t)\}$ is:
 :$$\varphi_y (\tau) = m_y^2 + \sigma_y^2 \cdot {\rm e}^{- \pi \hspace{0.03cm} \cdot \hspace{0.03cm}(\tau / {\rm \nabla} \tau_y)^2}.$$
-*On the right you can see the function progression.&nbsp; Related to the resistor&nbsp; $ R = 50 \hspace{0.05 cm}{\rm \Omega}$&nbsp; results in the following ACF values:
+*On the right you can see the ACF curve.&nbsp; Related to the resistor&nbsp; $ R = 50 \hspace{0.05 cm}{\rm \Omega}$&nbsp; results in the following ACF values:
 :$$\varphi_y (\tau = 0) = 5 \hspace{0.1cm} {\rm mW} , \hspace{0.5cm} \varphi_y (\tau \rightarrow \infty) = 1.8\hspace{0.1cm} {\rm mW} .$$
@@ Line 112: / Line 112: @@
 \hspace{0.15 cm}\underline{=1.938\hspace{0.05 cm}\rm mW}.$$
-*With positive mean&nbsp; $m_y$&nbsp; (having the same amplitude), there would be no change in the ASF, since&nbsp; $m_y$&nbsp; is squared in the ASF equation.
+*With positive mean&nbsp; $m_y$&nbsp; $($having the same magnitude$)$,&nbsp; there would be no change in the ACF,&nbsp; since&nbsp; $m_y$&nbsp; is squared in the ACF equation.
 {{ML-Fuß}}