Consider the circuit shown in the figure below. Use the following as necessary: R1 = 8.00 Ω, R2 = 1.30 Ω, and V = 7.00 V. (a) Calculate the equivalent resistance of the R1 and 5.00 Ω resistors connected in parallel. Ω (b) Using the result of part (a), calculate the combined resistance of the R1, 5.00 Ω, and 4.00 Ω resistors. Ω (c) Calculate the equivalent resistance of the combined resistance found in part (b) and the parallel 3.00 Ω resistor. Ω (d) Combine the equivalent resistance found in part (c) with the R2 resistor. Ω (e) Calculate the total current in the circuit. A (f) What is the voltage drop across the R2 resistor? V
Consider the circuit shown in the figure below. Use the following as necessary: R1 = 8.00 Ω, R2 = 1.30 Ω, and V = 7.00 V. (a) Calculate the equivalent resistance of the R1 and 5.00 Ω resistors connected in parallel. Ω (b) Using the result of part (a), calculate the combined resistance of the R1, 5.00 Ω, and 4.00 Ω resistors. Ω (c) Calculate the equivalent resistance of the combined resistance found in part (b) and the parallel 3.00 Ω resistor. Ω (d) Combine the equivalent resistance found in part (c) with the R2 resistor. Ω (e) Calculate the total current in the circuit. A (f) What is the voltage drop across the R2 resistor? V
College Physics
1st Edition
ISBN:9781938168000
Author:Paul Peter Urone, Roger Hinrichs
Publisher:Paul Peter Urone, Roger Hinrichs
Chapter1: Introduction: The Nature Of Science And Physics
Section: Chapter Questions
Problem 23PE: If a marathon runner averages 9.5 mi/h, how long does it take him or her to run a 26.22-mi marathon?
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Consider the circuit shown in the figure below. Use the following as necessary: R1 = 8.00 Ω, R2 = 1.30 Ω, and V = 7.00 V.
(a) Calculate the equivalent resistance of the R1 and 5.00 Ω resistors connected in parallel.
Ω
(b) Using the result of part (a), calculate the combined resistance of the R1, 5.00 Ω, and 4.00 Ω resistors.
Ω
(c) Calculate the equivalent resistance of the combined resistance found in part (b) and the parallel 3.00 Ω resistor.
Ω
(d) Combine the equivalent resistance found in part (c) with the R2 resistor.
Ω
(e) Calculate the total current in the circuit.
A
(f) What is the voltage drop across the R2 resistor?
V
(g) Subtracting the result of part (f) from the battery voltage, find the voltage across the 3.00 Ω resistor.
V
(h) Calculate the current in the 3.00 Ω resistor.
A
Ω
(b) Using the result of part (a), calculate the combined resistance of the R1, 5.00 Ω, and 4.00 Ω resistors.
Ω
(c) Calculate the equivalent resistance of the combined resistance found in part (b) and the parallel 3.00 Ω resistor.
Ω
(d) Combine the equivalent resistance found in part (c) with the R2 resistor.
Ω
(e) Calculate the total current in the circuit.
A
(f) What is the voltage drop across the R2 resistor?
V
(g) Subtracting the result of part (f) from the battery voltage, find the voltage across the 3.00 Ω resistor.
V
(h) Calculate the current in the 3.00 Ω resistor.
A
Transcribed Image Text:4.00 0
5.00 N
R2
3.00 N
V
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