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--- electrical_engineering_and_electronics_1:block05 [2025/09/28 23:50] – mexleadmin
+++ electrical_engineering_and_electronics_1:block05 [2026/01/10 13:23] (aktuell) – mexleadmin
@@ Zeile 1: / Zeile 1: @@
-====== Block 05 — Resistive networks ======
+====== Block 05 — Resistive Networks ======
-===== Learning objectives =====
+===== 5.0 Intro =====
+==== 5.0.1 Learning Objectives ====
 <callout>
 After this 90-minute block, you can
@@ Zeile 10: / Zeile 12: @@
 </callout>
+==== 5.0.2 Preparation at Home ====
+And again:
+  * Please read through the following chapter.
+  * Also here, there are some clips for more clarification under 'Embedded resources' (check the text above/below, sometimes only part of the clip is interesting).
+For checking your understanding please do the following exercises:
+  * 2.5.3
+  * 2.7.8
 ~~PAGEBREAK~~ ~~CLEARFIX~~
-===== 90-minute plan  =====
+==== 5.0.3 90-minute Plan  ====
   * 0–10 min — Recap KCL/KVL; sign conventions.
   * 10–30 min — Series & parallel; quick numeric checks.
@@ Zeile 21: / Zeile 32: @@
 ~~PAGEBREAK~~ ~~CLEARFIX~~
-===== Core Content =====
+===== 5.1 Core Content =====
-==== Unloaded voltage divider ====
+==== 5.1.1 Unloaded Voltage Divider ====
 The series circuit of two resistors $R_1$ and $R_2$ shall be considered now. \\
@@ Zeile 48: / Zeile 59: @@
 ~~PAGEBREAK~~ ~~CLEARFIX~~
-<panel type="info" title="Exercise 2.5.1 unloaded voltage divider"> <WRAP group><WRAP column 2%>{{fa>pencil?32}}</WRAP><WRAP column 92%>
+<panel type="info" title="Exercise"> <WRAP group><WRAP column 2%>{{fa>pencil?32}}</WRAP><WRAP column 92%>
 <WRAP>
@@ Zeile 63: / Zeile 74: @@
 ~~PAGEBREAK~~ ~~CLEARFIX~~
-==== The loaded Voltage Divider ====
+==== 5.1.2 The loaded Voltage Divider ====
 If - in contrast to the abovementioned, unloaded voltage divider - a load $R_{\rm L}$ is connected to the output terminals (<imgref BildNr15>), this load influences the output voltage.
@@ Zeile 77: / Zeile 88: @@
 $ U_1 = \LARGE{{U} \over {1 + {{R_2}\over{R_L}} + {{R_2}\over{R_1}} }}$
-or on a potentiometer with $k$ and the sum of resistors $R_{\rm s} = R_1 + R_2$:
+An alternative representation of the formula sticks more to the application. \\
+It uses:
+  - the position on a potentiometer given as $k={{R_1}\over{R_1 + R_2}}$ and
+  - the sum of resistors $R_{\rm s} = R_1 + R_2$.
+Both are more often used in real setups.
-$ U_1 = \LARGE{{k \cdot U} \over { 1 + k \cdot (1-k) \cdot{{R_{\rm s}}\over{R_{\rm L}}} }}$
+Mathematically, both parameter lead to $R_1 = k \cdot R_{\rm s}$ and $R_2 = (1 - k) \cdot R_{\rm s}$. \\
+When these tyo relations are included in rhe the formula above, we get:
+$ U_1 = U \cdot k \cdot \LARGE{{1} \over { 1 + k \cdot (1-k) \cdot{{R_{\rm s}}\over{R_{\rm L}}} }}$
 <imgref BildNr65> shows the ratio of the output voltage $U_1$ to the input voltage $U$ (y-axis), in relation to the ratio $k={{R_1}\over{R_1 + R_2}}$.
@@ Zeile 98: / Zeile 116: @@
 ~~PAGEBREAK~~ ~~CLEARFIX~~
-==== Bridge networks (Wheatstone) ====
+==== 5.1.3 Bridge Networks (Wheatstone) ====
 A four-resistor bridge can be seen as **two voltage dividers in parallel**. The detector (bridge branch) sees the **difference** of the two divider node voltages. The **balance condition** (zero detector current) is
 \begin{align*}
@@ Zeile 110: / Zeile 128: @@
 ~~PAGEBREAK~~ ~~CLEARFIX~~
-==== Strategy for network reduction ====
+==== 5.1.4 Strategy for network reduction ====
   * Reshape (without changing node connections), then collapse **clear** series or parallel groups.
-  * If blocked by a three-terminal cluster, apply **Δ–Y** (or **Y–Δ**), then collapse again.
+  * (If blocked by a three-terminal cluster, apply **Δ–Y** (or **Y–Δ**), then collapse again. {{wp>Y-Δ_transform|Y–Δ and Δ–Y}} ist not covered and necessary in this course)
   * Repeat until a simple ladder remains; finish with KCL/KVL if needed.
@@ Zeile 150: / Zeile 168: @@
 ~~PAGEBREAK~~ ~~CLEARFIX~~
-===== Exercises =====
+===== 5.2 Exercises =====
 <panel type="info" title="Exercise 2.4.3 Three Resistors"> <WRAP group><WRAP column 2%>{{fa>pencil?32}}</WRAP><WRAP column 92%>
@@ Zeile 290: / Zeile 308: @@
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-{{page>aufgabe_2.7.10&nofooter}}
+{{page>electrical_engineering_and_electronics:aufgabe_2.7.10&nofooter}}
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+{{page>electrical_engineering_and_electronics:task_erlctd760zmvox0t_with_calculation&nofooter}}
+{{page>electrical_engineering_and_electronics:task_x357drkaqv84jnsc_with_calculation&nofooter}}