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--- electrical_engineering_1:network_analysis [2023/11/23 03:02] – mexleadmin
+++ electrical_engineering_1:network_analysis [2025/01/29 00:30] (aktuell) – mexleadmin
@@ Zeile 406: / Zeile 406: @@
 For conditioning, the input signal is to be fed via the series resistor $R_3$ to the center potential of a voltage divider $R_1 - R_2$ with $R_1$ to a supply voltage $U_{\rm s}$.
-The following simulation shows roughly the situation (the resistor values are not correct).
+The following simulation shows roughly the situation. Be aware that the resistor and voltage values are not correct!
-<WRAP>{{url>https://www.falstad.com/circuit/circuitjs.html?running=false&ctz=CQAgjCDMCmC0DsIBskB08CcGkA4AsYGADEQKxFIYjnUh6TVxhgBQATiLHjiAEy95kg-oKLgSJdkL4DpkIqOoSiUpMNlrwSMWN4SWAczkK5ekDpYAlaWG03ePHXTGlzboqlIsAbp0K8oE1h-PjwnCDC+Jx1PQz8MAPlBYISoMwsAd3iAgTEUnNkVDnyZZOxStzB9SFxpEQr6iwAjTl5SJHA8ZOZEgnMWAA9W0kSkRFgMCEgMRGFBJoBLAAcAewAbAEM2AB0AZwBlFYBXNgBjaD3t7YA7AApoVANUPY293ehr3ZW2AEpBkFShAYVSohA6cxAln+zF0REQYF4DF4VTooXA0IRfHgwLaWPBaN4-wwwlIoOYfCQAQhUKGwR4enGrmRYghkH+sBq4AwDBSXPxshp4Bwoymtigk1RsiO12W6y2bwW1wA1lc7g8nnsjgBhH5-SDwPLlepcemyCAWWlgHA8K3deAQK2zNGC4KULk8sCkYHlCH7FgrAHiQrODD0sRIVCKAKuFRAA noborder}} </WRAP>
+<WRAP>{{url>https://www.falstad.com/circuit/circuitjs.html?ctz=CQAgjCBMCmC0AcUB08AMBmMA2SAWeAnLgKyRZi4jGpUi7pVxhgBQATiFpZHp5djRrVULAEp9wWGl3CREgukJALUSYiwBuIWGAKQQ6VJR16ouBRHOprUFcrUsA5tt37Dx1wcgqWAdxemeDQm+jyUIhwhULywBFjR4eDWIuhYiDJhCVmCLABG2pDE8RQeYG64ECIAHgWkBlgA7NoEEOgETdyUuQCWAA4A9gA2AIZsADoAzgDK-QCubADG0JNjYwB2ABTQSI5Ik8OTE9BrE-1sAJQsNQQE4AQMzMVxdGYgolfgYE3eTWCGUGAaJ1wB9HlB4BAyrc5JRgZAPgREGRfmBiFAGkDXu8amB4G5yAZsAYWi9eLM1n0hqNDt01gBrVabba7SazADC50u6AxzXimVg+CylWUHx08EQuI8DUh8A6WNF2FuugYOmID2ewKm7AkmRk7mUVGS2oyMUFmRo3msTgk+r13gN1W0-Fl4HVmN42PA3FQEEg3yMpMo6BY-U4kgN5kRtk4SESoRFQA noborder}} </WRAP>
 Questions:
-. Find the relationship between $R_1$, $R_2$, and $R_3$ using superposition.
+. Find the relationship between $R_1$, $R_2$, and $R_3$ using superposition. \\
+  * Determine suitable values for $R_1$, $R_2$, and $R_3$.
+  * What values for $R^0_1$, $R^0_2$, and $R^0_3$ from the [[https://de.wikipedia.org/wiki/E-Reihe|E24 series]] can be used to do this?
 #@HiddenBegin_HTML~1,Solution~@#
@@ Zeile 456: / Zeile 458: @@
 \end{align*}
-The formula $(1)$ is the general formula to calculate the output voltage $U_{\rm O}$ for a changing input voltage $U_{\rm I}$, where the supply voltage $U_{\rm S}" is constant. \\
+The formula $(1)$ is the general formula to calculate the output voltage $U_{\rm O}$ for a changing input voltage $U_{\rm I}$, where the supply voltage $U_{\rm S}$ is constant. \\
 </callout>
@@ Zeile 531: / Zeile 533: @@
 R_2 &= {{1}\over{5.09}}(R_3 + 15 {~\rm k\Omega}) = 11.8 {~\rm k\Omega}
 \end{align*}
+Based on the E24 series, the following values are next to the calculated ones:
+\begin{align*}
+R_3^0 &= 43 {~\rm k\Omega}\\
+R_1^0 &= {{1}\over{3}}   (R_3 + 15 {~\rm k\Omega}) = 20 {~\rm k\Omega} \\
+R_2^0 &= {{1}\over{5.09}}(R_3 + 15 {~\rm k\Omega}) = 12 {~\rm k\Omega}
+\end{align*}
 #@HiddenEnd_HTML~Result1,Result~@#
+. Find the relationship between $R_1$, $R_2$, and $R_3$ by investigating Kirchhoff's nodal rule for the node where $R_1$, $R_2$, and $R_3$ are interconnected.
+#@HiddenBegin_HTML~Solution2,Solution~@#
+The potential of the node is $U_\rm O$. Therefore the currents are:
+  - the current $I_2$ over $R_2$ is flowing to ground: $I_2 = - {{U_\rm O}\over{R_2}} $
+  - the current $I_1$ over $R_1$ is coming from the supply voltage $U_{\rm S}$ to the nodal voltage $U_{\rm O}$:  $I_1 = {{U_{\rm S} - U_{\rm O}}\over{R_1}}$
+  - the current $I_4$ over $R_4$ is coming from the input voltage  $U_{\rm I}$ to the nodal voltage $U_{\rm O}$:  $I_4 = {{U_{\rm I} - U_{\rm O}}\over{R_4}}$
+This led to the formula based on the Kirchhoff's nodal rule:
+\begin{align*}
+\Sigma I = 0 &= I_1 + I_2 + I_3 \\
+&= {{U_{\rm S} - U_{\rm O}}\over{R_1}} + {{U_{\rm I} - U_{\rm O}}\over{R_4}} - {{U_\rm O}\over{R_2}}
+\end{align*}
+The formula can be rearranged, with all terms containing $ U_{\rm O}$ on the left side:
+\begin{align*}
+    {{U_{\rm O}}\over{R_1}} + {{U_{\rm O}}\over{R_2}} + {{U_{\rm O}}\over{R_4}}         &=  {{U_{\rm S}}\over{R_1}}  + {{U_{\rm I}}\over{R_4}}  \\
+      U_{\rm O}\cdot \left( {{1}\over{R_1}} + {{1}\over{R_2}} + {{1}\over{R_4}} \right) &=  {{U_{\rm S}}\over{R_1}}  + {{U_{\rm I}}\over{R_4}}  \\
+\end{align*}
+Both sides can be multiplied by $\cdot R_1$, $\cdot R_2$, $\cdot R_4$  - in order to get rid of the fractions :
+\begin{align*}
+      U_{\rm O}\cdot \left( {{R_1 R_2 R_4 }\over{R_1}} + {{R_1 R_2 R_4 }\over{R_2}} + {{R_1 R_2 R_4 }\over{R_4}} \right) &=  R_1 R_2 R_4 \cdot {{U_{\rm S}}\over{R_1}}  + R_1 R_2 R_4 \cdot {{U_{\rm I}}\over{R_4}}  \\
+      U_{\rm O}\cdot \left( R_2 R_4 + R_1 R_4 + R_1 R_2 \right) &=  R_2 R_4 \cdot U_{\rm S}  + R_1 R_2 \cdot U_{\rm I} \\
+      U_{\rm O} &= {{R_2}\over{R_2 R_4 + R_1 R_4 + R_1 R_2 }}  \left( R_4 \cdot U_{\rm S}  + R_1 \cdot U_{\rm I} \right)\\
+\end{align*}
+The last formula was just the result we also got by the superposition but by more thinking. \\
+So, sometimes there is an easier way...
+  * Unluckily, there is no simple way to know before, what way is the easiest.
+  * Luckily, all ways lead to the correct result.
+#@HiddenEnd_HTML~Solution2,Solution ~@#
+. What is the input resistance $R_{\rm in}(R_1, R_2, R_3)$ of the circuit (viewed from the sensor)?
+#@HiddenBegin_HTML~Solution3,Solution~@#
+\begin{align*}
+R_{\rm in}(R_1, R_2, R_3) &= R_3 + R_1 || R_2 \\
+                          &= R_3 + {{R_1  R_2}\over{R_1 + R_2}}
+\end{align*}
+#@HiddenEnd_HTML~Solution3,Solution~@#
+. What is the minimum allowed input resistance ($R_{\rm in, min}(R_1, R_2, R_3)$) for the sensor to still deliver current?
+#@HiddenBegin_HTML~Solution4,Solution~@#
+\begin{align*}
+R_{\rm in, min} &= {{U_{\rm sense}}\over{I_{\rm sense, max}}} \\
+                &= \rm {{15 V}\over{1 mA}} \\
+                &= 15 k\Omega \\
+\end{align*}
+#@HiddenEnd_HTML~Solution4,Solution~@#
-  * Find the relationship between $R_1$, $R_2$, and $R_3$ using the star-delta transformation.
-  * What is the input resistance $R_{\rm in}(R_1, R_2, R_3)$ of the circuit (viewed from the sensor)?
-  * What is the maximum allowed input resistance ($R_{\rm in}(R_1, R_2, R_3)$) for the sensor to still deliver current?
-  * Determine suitable values for $R_1$, $R_2$, and $R_3$.
-  * What values for $R^0_1$, $R^0_2$, and $R^0_3$ from the [[https://de.wikipedia.org/wiki/E-Reihe|E24 series]] can be used to do this?
-  *
 #@TaskEnd_HTML@#