Solved PARALLEL CIRCUIT PROBLEMS Use Ohms Law and the rules ... - Free Printable
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Step-by-step solution for: Solved PARALLEL CIRCUIT PROBLEMS Use Ohms Law and the rules ...
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Step-by-step solution for: Solved PARALLEL CIRCUIT PROBLEMS Use Ohms Law and the rules ...
To solve the problems in the image, we need to analyze each circuit step by step using basic principles of electrical circuits, such as Ohm's Law (\( V = IR \)) and the rules for series and parallel resistances. Let's go through each problem systematically.
---
Circuit: Series circuit with \( R_1 = 3 \Omega \) and \( R_2 = 6 \Omega \), \( V_T = 6 \, \text{V} \).
#### Solution:
1. Total Resistance (\( R_T \)):
\[
R_T = R_1 + R_2 = 3 \, \Omega + 6 \, \Omega = 9 \, \Omega
\]
2. Total Current (\( I_T \)):
Using Ohm's Law:
\[
I_T = \frac{V_T}{R_T} = \frac{6 \, \text{V}}{9 \, \Omega} = \frac{2}{3} \, \text{A} \approx 0.67 \, \text{A}
\]
3. Voltage across \( R_1 \) (\( V_1 \)):
\[
V_1 = I_T \cdot R_1 = \frac{2}{3} \, \text{A} \cdot 3 \, \Omega = 2 \, \text{V}
\]
4. Voltage across \( R_2 \) (\( V_2 \)):
\[
V_2 = I_T \cdot R_2 = \frac{2}{3} \, \text{A} \cdot 6 \, \Omega = 4 \, \text{V}
\]
Answers:
\[
V_1 = 2 \, \text{V}, \quad I_1 = \frac{2}{3} \, \text{A}, \quad I_2 = \frac{2}{3} \, \text{A}, \quad V_2 = 4 \, \text{V}, \quad R_T = 9 \, \Omega
\]
---
Circuit: Series circuit with \( R_1 = 5 \, \Omega \) and \( R_2 = 2 \, \Omega \), \( V_T = 40 \, \text{V} \).
#### Solution:
1. Total Resistance (\( R_T \)):
\[
R_T = R_1 + R_2 = 5 \, \Omega + 2 \, \Omega = 7 \, \Omega
\]
2. Total Current (\( I_T \)):
Using Ohm's Law:
\[
I_T = \frac{V_T}{R_T} = \frac{40 \, \text{V}}{7 \, \Omega} \approx 5.71 \, \text{A}
\]
3. Voltage across \( R_1 \) (\( V_1 \)):
\[
V_1 = I_T \cdot R_1 = 5.71 \, \text{A} \cdot 5 \, \Omega \approx 28.57 \, \text{V}
\]
4. Voltage across \( R_2 \) (\( V_2 \)):
\[
V_2 = I_T \cdot R_2 = 5.71 \, \text{A} \cdot 2 \, \Omega \approx 11.43 \, \text{V}
\]
Answers:
\[
R_T = 7 \, \Omega, \quad I_1 = 5.71 \, \text{A}, \quad I_2 = 5.71 \, \text{A}, \quad V_1 = 28.57 \, \text{V}, \quad V_2 = 11.43 \, \text{V}
\]
---
Circuit: Parallel circuit with \( R_1 = 24 \, \Omega \) and \( R_2 = 48 \, \Omega \), \( I_T = 3 \, \text{A} \).
#### Solution:
1. Total Resistance (\( R_T \)):
For parallel resistors:
\[
\frac{1}{R_T} = \frac{1}{R_1} + \frac{1}{R_2} = \frac{1}{24} + \frac{1}{48} = \frac{2}{48} + \frac{1}{48} = \frac{3}{48} = \frac{1}{16}
\]
\[
R_T = 16 \, \Omega
\]
2. Total Voltage (\( V_T \)):
Using Ohm's Law:
\[
V_T = I_T \cdot R_T = 3 \, \text{A} \cdot 16 \, \Omega = 48 \, \text{V}
\]
3. Current through \( R_1 \) (\( I_1 \)):
\[
I_1 = \frac{V_T}{R_1} = \frac{48 \, \text{V}}{24 \, \Omega} = 2 \, \text{A}
\]
4. Current through \( R_2 \) (\( I_2 \)):
\[
I_2 = \frac{V_T}{R_2} = \frac{48 \, \text{V}}{48 \, \Omega} = 1 \, \text{A}
\]
5. Voltage across \( R_1 \) (\( V_1 \)):
\[
V_1 = V_T = 48 \, \text{V}
\]
6. Voltage across \( R_2 \) (\( V_2 \)):
\[
V_2 = V_T = 48 \, \text{V}
\]
Answers:
\[
R_T = 16 \, \Omega, \quad V_T = 48 \, \text{V}, \quad V_1 = 48 \, \text{V}, \quad V_2 = 48 \, \text{V}, \quad I_1 = 2 \, \text{A}, \quad I_2 = 1 \, \text{A}
\]
---
Circuit: Parallel circuit with \( R_1 = 6 \, \Omega \) and \( R_2 = 12 \, \Omega \), \( I_T = 3 \, \text{A} \).
#### Solution:
1. Total Resistance (\( R_T \)):
For parallel resistors:
\[
\frac{1}{R_T} = \frac{1}{R_1} + \frac{1}{R_2} = \frac{1}{6} + \frac{1}{12} = \frac{2}{12} + \frac{1}{12} = \frac{3}{12} = \frac{1}{4}
\]
\[
R_T = 4 \, \Omega
\]
2. Total Voltage (\( V_T \)):
Using Ohm's Law:
\[
V_T = I_T \cdot R_T = 3 \, \text{A} \cdot 4 \, \Omega = 12 \, \text{V}
\]
3. Current through \( R_1 \) (\( I_1 \)):
\[
I_1 = \frac{V_T}{R_1} = \frac{12 \, \text{V}}{6 \, \Omega} = 2 \, \text{A}
\]
4. Current through \( R_2 \) (\( I_2 \)):
\[
I_2 = \frac{V_T}{R_2} = \frac{12 \, \text{V}}{12 \, \Omega} = 1 \, \text{A}
\]
5. Voltage across \( R_1 \) (\( V_1 \)):
\[
V_1 = V_T = 12 \, \text{V}
\]
6. Voltage across \( R_2 \) (\( V_2 \)):
\[
V_2 = V_T = 12 \, \text{V}
\]
Answers:
\[
R_T = 4 \, \Omega, \quad V_T = 12 \, \text{V}, \quad V_1 = 12 \, \text{V}, \quad V_2 = 12 \, \text{V}, \quad I_1 = 2 \, \text{A}, \quad I_2 = 1 \, \text{A}
\]
---
Circuit: Series circuit with \( R_1 = 10 \, \Omega \) and \( R_2 = 10 \, \Omega \), \( V_T = 40 \, \text{V} \), \( I_T = 5 \, \text{A} \).
#### Solution:
1. Total Resistance (\( R_T \)):
\[
R_T = R_1 + R_2 = 10 \, \Omega + 10 \, \Omega = 20 \, \Omega
\]
2. Voltage across \( R_1 \) (\( V_1 \)):
\[
V_1 = I_T \cdot R_1 = 5 \, \text{A} \cdot 10 \, \Omega = 50 \, \text{V}
\]
3. Voltage across \( R_2 \) (\( V_2 \)):
\[
V_2 = I_T \cdot R_2 = 5 \, \text{A} \cdot 10 \, \Omega = 50 \, \text{V}
\]
Answers:
\[
V_1 = 50 \, \text{V}, \quad I_1 = 5 \, \text{A}, \quad I_2 = 5 \, \text{A}, \quad V_2 = 50 \, \text{V}
\]
---
Circuit: Series circuit with \( R_1 = 12 \, \Omega \) and \( R_2 = 24 \, \Omega \), \( V_T = 24 \, \text{V} \).
#### Solution:
1. Total Resistance (\( R_T \)):
\[
R_T = R_1 + R_2 = 12 \, \Omega + 24 \, \Omega = 36 \, \Omega
\]
2. Total Current (\( I_T \)):
Using Ohm's Law:
\[
I_T = \frac{V_T}{R_T} = \frac{24 \, \text{V}}{36 \, \Omega} = \frac{2}{3} \, \text{A} \approx 0.67 \, \text{A}
\]
3. Voltage across \( R_1 \) (\( V_1 \)):
\[
V_1 = I_T \cdot R_1 = \frac{2}{3} \, \text{A} \cdot 12 \, \Omega = 8 \, \text{V}
\]
4. Voltage across \( R_2 \) (\( V_2 \)):
\[
V_2 = I_T \cdot R_2 = \frac{2}{3} \, \text{A} \cdot 24 \, \Omega = 16 \, \text{V}
\]
Answers:
\[
V_1 = 8 \, \text{V}, \quad I_1 = \frac{2}{3} \, \text{A}, \quad I_2 = \frac{2}{3} \, \text{A}, \quad V_2 = 16 \, \text{V}, \quad R_T = 36 \, \Omega
\]
---
Circuit: Series circuit with \( R_1 = 5 \, \Omega \), \( R_2 = 20 \, \Omega \), and \( R_3 = 4 \, \Omega \).
#### Solution:
1. Total Resistance (\( R_T \)):
\[
R_T = R_1 + R_2 + R_3 = 5 \, \Omega + 20 \, \Omega + 4 \, \Omega = 29 \, \Omega
\]
Answer:
\[
R_T = 29 \, \Omega
\]
---
Circuit: Series circuit with \( R_1 = 48 \, \Omega \), \( R_2 = 16 \, \Omega \), and \( R_3 = 24 \, \Omega \).
#### Solution:
1. Total Resistance (\( R_T \)):
\[
R_T = R_1 + R_2 + R_3 = 48 \, \Omega + 16 \, \Omega + 24 \, \Omega = 88 \, \Omega
\]
Answer:
\[
R_T = 88 \, \Omega
\]
---
\[
\boxed{
\begin{array}{l}
\text{Problem 1: } V_1 = 2 \, \text{V}, \, I_1 = \frac{2}{3} \, \text{A}, \, I_2 = \frac{2}{3} \, \text{A}, \, V_2 = 4 \, \text{V}, \, R_T = 9 \, \Omega \\
\text{Problem 2: } R_T = 7 \, \Omega, \, I_1 = 5.71 \, \text{A}, \, I_2 = 5.71 \, \text{A}, \, V_1 = 28.57 \, \text{V}, \, V_2 = 11.43 \, \text{V} \\
\text{Problem 3: } R_T = 16 \, \Omega, \, V_T = 48 \, \text{V}, \, V_1 = 48 \, \text{V}, \, V_2 = 48 \, \text{V}, \, I_1 = 2 \, \text{A}, \, I_2 = 1 \, \text{A} \\
\text{Problem 4: } R_T = 4 \, \Omega, \, V_T = 12 \, \text{V}, \, V_1 = 12 \, \text{V}, \, V_2 = 12 \, \text{V}, \, I_1 = 2 \, \text{A}, \, I_2 = 1 \, \text{A} \\
\text{Problem 5: } V_1 = 50 \, \text{V}, \, I_1 = 5 \, \text{A}, \, I_2 = 5 \, \text{A}, \, V_2 = 50 \, \text{V} \\
\text{Problem 6: } V_1 = 8 \, \text{V}, \, I_1 = \frac{2}{3} \, \text{A}, \, I_2 = \frac{2}{3} \, \text{A}, \, V_2 = 16 \, \text{V}, \, R_T = 36 \, \Omega \\
\text{Problem 7: } R_T = 29 \, \Omega \\
\text{Problem 8: } R_T = 88 \, \Omega
\end{array}
}
\]
---
Problem 1:
Circuit: Series circuit with \( R_1 = 3 \Omega \) and \( R_2 = 6 \Omega \), \( V_T = 6 \, \text{V} \).
#### Solution:
1. Total Resistance (\( R_T \)):
\[
R_T = R_1 + R_2 = 3 \, \Omega + 6 \, \Omega = 9 \, \Omega
\]
2. Total Current (\( I_T \)):
Using Ohm's Law:
\[
I_T = \frac{V_T}{R_T} = \frac{6 \, \text{V}}{9 \, \Omega} = \frac{2}{3} \, \text{A} \approx 0.67 \, \text{A}
\]
3. Voltage across \( R_1 \) (\( V_1 \)):
\[
V_1 = I_T \cdot R_1 = \frac{2}{3} \, \text{A} \cdot 3 \, \Omega = 2 \, \text{V}
\]
4. Voltage across \( R_2 \) (\( V_2 \)):
\[
V_2 = I_T \cdot R_2 = \frac{2}{3} \, \text{A} \cdot 6 \, \Omega = 4 \, \text{V}
\]
Answers:
\[
V_1 = 2 \, \text{V}, \quad I_1 = \frac{2}{3} \, \text{A}, \quad I_2 = \frac{2}{3} \, \text{A}, \quad V_2 = 4 \, \text{V}, \quad R_T = 9 \, \Omega
\]
---
Problem 2:
Circuit: Series circuit with \( R_1 = 5 \, \Omega \) and \( R_2 = 2 \, \Omega \), \( V_T = 40 \, \text{V} \).
#### Solution:
1. Total Resistance (\( R_T \)):
\[
R_T = R_1 + R_2 = 5 \, \Omega + 2 \, \Omega = 7 \, \Omega
\]
2. Total Current (\( I_T \)):
Using Ohm's Law:
\[
I_T = \frac{V_T}{R_T} = \frac{40 \, \text{V}}{7 \, \Omega} \approx 5.71 \, \text{A}
\]
3. Voltage across \( R_1 \) (\( V_1 \)):
\[
V_1 = I_T \cdot R_1 = 5.71 \, \text{A} \cdot 5 \, \Omega \approx 28.57 \, \text{V}
\]
4. Voltage across \( R_2 \) (\( V_2 \)):
\[
V_2 = I_T \cdot R_2 = 5.71 \, \text{A} \cdot 2 \, \Omega \approx 11.43 \, \text{V}
\]
Answers:
\[
R_T = 7 \, \Omega, \quad I_1 = 5.71 \, \text{A}, \quad I_2 = 5.71 \, \text{A}, \quad V_1 = 28.57 \, \text{V}, \quad V_2 = 11.43 \, \text{V}
\]
---
Problem 3:
Circuit: Parallel circuit with \( R_1 = 24 \, \Omega \) and \( R_2 = 48 \, \Omega \), \( I_T = 3 \, \text{A} \).
#### Solution:
1. Total Resistance (\( R_T \)):
For parallel resistors:
\[
\frac{1}{R_T} = \frac{1}{R_1} + \frac{1}{R_2} = \frac{1}{24} + \frac{1}{48} = \frac{2}{48} + \frac{1}{48} = \frac{3}{48} = \frac{1}{16}
\]
\[
R_T = 16 \, \Omega
\]
2. Total Voltage (\( V_T \)):
Using Ohm's Law:
\[
V_T = I_T \cdot R_T = 3 \, \text{A} \cdot 16 \, \Omega = 48 \, \text{V}
\]
3. Current through \( R_1 \) (\( I_1 \)):
\[
I_1 = \frac{V_T}{R_1} = \frac{48 \, \text{V}}{24 \, \Omega} = 2 \, \text{A}
\]
4. Current through \( R_2 \) (\( I_2 \)):
\[
I_2 = \frac{V_T}{R_2} = \frac{48 \, \text{V}}{48 \, \Omega} = 1 \, \text{A}
\]
5. Voltage across \( R_1 \) (\( V_1 \)):
\[
V_1 = V_T = 48 \, \text{V}
\]
6. Voltage across \( R_2 \) (\( V_2 \)):
\[
V_2 = V_T = 48 \, \text{V}
\]
Answers:
\[
R_T = 16 \, \Omega, \quad V_T = 48 \, \text{V}, \quad V_1 = 48 \, \text{V}, \quad V_2 = 48 \, \text{V}, \quad I_1 = 2 \, \text{A}, \quad I_2 = 1 \, \text{A}
\]
---
Problem 4:
Circuit: Parallel circuit with \( R_1 = 6 \, \Omega \) and \( R_2 = 12 \, \Omega \), \( I_T = 3 \, \text{A} \).
#### Solution:
1. Total Resistance (\( R_T \)):
For parallel resistors:
\[
\frac{1}{R_T} = \frac{1}{R_1} + \frac{1}{R_2} = \frac{1}{6} + \frac{1}{12} = \frac{2}{12} + \frac{1}{12} = \frac{3}{12} = \frac{1}{4}
\]
\[
R_T = 4 \, \Omega
\]
2. Total Voltage (\( V_T \)):
Using Ohm's Law:
\[
V_T = I_T \cdot R_T = 3 \, \text{A} \cdot 4 \, \Omega = 12 \, \text{V}
\]
3. Current through \( R_1 \) (\( I_1 \)):
\[
I_1 = \frac{V_T}{R_1} = \frac{12 \, \text{V}}{6 \, \Omega} = 2 \, \text{A}
\]
4. Current through \( R_2 \) (\( I_2 \)):
\[
I_2 = \frac{V_T}{R_2} = \frac{12 \, \text{V}}{12 \, \Omega} = 1 \, \text{A}
\]
5. Voltage across \( R_1 \) (\( V_1 \)):
\[
V_1 = V_T = 12 \, \text{V}
\]
6. Voltage across \( R_2 \) (\( V_2 \)):
\[
V_2 = V_T = 12 \, \text{V}
\]
Answers:
\[
R_T = 4 \, \Omega, \quad V_T = 12 \, \text{V}, \quad V_1 = 12 \, \text{V}, \quad V_2 = 12 \, \text{V}, \quad I_1 = 2 \, \text{A}, \quad I_2 = 1 \, \text{A}
\]
---
Problem 5:
Circuit: Series circuit with \( R_1 = 10 \, \Omega \) and \( R_2 = 10 \, \Omega \), \( V_T = 40 \, \text{V} \), \( I_T = 5 \, \text{A} \).
#### Solution:
1. Total Resistance (\( R_T \)):
\[
R_T = R_1 + R_2 = 10 \, \Omega + 10 \, \Omega = 20 \, \Omega
\]
2. Voltage across \( R_1 \) (\( V_1 \)):
\[
V_1 = I_T \cdot R_1 = 5 \, \text{A} \cdot 10 \, \Omega = 50 \, \text{V}
\]
3. Voltage across \( R_2 \) (\( V_2 \)):
\[
V_2 = I_T \cdot R_2 = 5 \, \text{A} \cdot 10 \, \Omega = 50 \, \text{V}
\]
Answers:
\[
V_1 = 50 \, \text{V}, \quad I_1 = 5 \, \text{A}, \quad I_2 = 5 \, \text{A}, \quad V_2 = 50 \, \text{V}
\]
---
Problem 6:
Circuit: Series circuit with \( R_1 = 12 \, \Omega \) and \( R_2 = 24 \, \Omega \), \( V_T = 24 \, \text{V} \).
#### Solution:
1. Total Resistance (\( R_T \)):
\[
R_T = R_1 + R_2 = 12 \, \Omega + 24 \, \Omega = 36 \, \Omega
\]
2. Total Current (\( I_T \)):
Using Ohm's Law:
\[
I_T = \frac{V_T}{R_T} = \frac{24 \, \text{V}}{36 \, \Omega} = \frac{2}{3} \, \text{A} \approx 0.67 \, \text{A}
\]
3. Voltage across \( R_1 \) (\( V_1 \)):
\[
V_1 = I_T \cdot R_1 = \frac{2}{3} \, \text{A} \cdot 12 \, \Omega = 8 \, \text{V}
\]
4. Voltage across \( R_2 \) (\( V_2 \)):
\[
V_2 = I_T \cdot R_2 = \frac{2}{3} \, \text{A} \cdot 24 \, \Omega = 16 \, \text{V}
\]
Answers:
\[
V_1 = 8 \, \text{V}, \quad I_1 = \frac{2}{3} \, \text{A}, \quad I_2 = \frac{2}{3} \, \text{A}, \quad V_2 = 16 \, \text{V}, \quad R_T = 36 \, \Omega
\]
---
Problem 7:
Circuit: Series circuit with \( R_1 = 5 \, \Omega \), \( R_2 = 20 \, \Omega \), and \( R_3 = 4 \, \Omega \).
#### Solution:
1. Total Resistance (\( R_T \)):
\[
R_T = R_1 + R_2 + R_3 = 5 \, \Omega + 20 \, \Omega + 4 \, \Omega = 29 \, \Omega
\]
Answer:
\[
R_T = 29 \, \Omega
\]
---
Problem 8:
Circuit: Series circuit with \( R_1 = 48 \, \Omega \), \( R_2 = 16 \, \Omega \), and \( R_3 = 24 \, \Omega \).
#### Solution:
1. Total Resistance (\( R_T \)):
\[
R_T = R_1 + R_2 + R_3 = 48 \, \Omega + 16 \, \Omega + 24 \, \Omega = 88 \, \Omega
\]
Answer:
\[
R_T = 88 \, \Omega
\]
---
Final Answers:
\[
\boxed{
\begin{array}{l}
\text{Problem 1: } V_1 = 2 \, \text{V}, \, I_1 = \frac{2}{3} \, \text{A}, \, I_2 = \frac{2}{3} \, \text{A}, \, V_2 = 4 \, \text{V}, \, R_T = 9 \, \Omega \\
\text{Problem 2: } R_T = 7 \, \Omega, \, I_1 = 5.71 \, \text{A}, \, I_2 = 5.71 \, \text{A}, \, V_1 = 28.57 \, \text{V}, \, V_2 = 11.43 \, \text{V} \\
\text{Problem 3: } R_T = 16 \, \Omega, \, V_T = 48 \, \text{V}, \, V_1 = 48 \, \text{V}, \, V_2 = 48 \, \text{V}, \, I_1 = 2 \, \text{A}, \, I_2 = 1 \, \text{A} \\
\text{Problem 4: } R_T = 4 \, \Omega, \, V_T = 12 \, \text{V}, \, V_1 = 12 \, \text{V}, \, V_2 = 12 \, \text{V}, \, I_1 = 2 \, \text{A}, \, I_2 = 1 \, \text{A} \\
\text{Problem 5: } V_1 = 50 \, \text{V}, \, I_1 = 5 \, \text{A}, \, I_2 = 5 \, \text{A}, \, V_2 = 50 \, \text{V} \\
\text{Problem 6: } V_1 = 8 \, \text{V}, \, I_1 = \frac{2}{3} \, \text{A}, \, I_2 = \frac{2}{3} \, \text{A}, \, V_2 = 16 \, \text{V}, \, R_T = 36 \, \Omega \\
\text{Problem 7: } R_T = 29 \, \Omega \\
\text{Problem 8: } R_T = 88 \, \Omega
\end{array}
}
\]
Parent Tip: Review the logic above to help your child master the concept of parallel circuit problems worksheet answers.