10. GP Consider the circuit shown in Figure P18.10. (a) Calcu-late the equivalent resistance of the 10.0-0 and 5.00- resis-tors connected in parallel. (b) Using the result of part (a),calculate the combined resistance of the 10.0-02, 5.00-02, and4.00- resistors. (c) Calculate the equivalent resistance of thecombined resistance found in part (b) and the parallel 3.00-2resistor. (d) Combine the equivalent resistance found in part(c) with the 2.00- resistor. (e) Calculate the total current inthe circuit. (f) What is the voltage drop across the 2.00- resis-tor? (g) Subtracting the result of part (f) from the battery volt-age, find the voltage across the 3.00- resistor. (h) Calculatethe current in the 3.00- resistor.2.00 Ωwww10.0w5.00 ΩW4.000www3.00 Ωwww8.00 VHHFigure P18.10m

Kirchhoffs First Law – The Current Law, (KCL)Kirchhoffs Current Law or KCL, states that the “total…

10. GP Consider the circuit shown in Figure P18.10. (a) Calcu- late the equivalent resistance of the 10.0-0 and 5.00- resis- tors connected in parallel. (b) Using the result of part (a), calculate the combined resistance of the 10.0-02, 5.00-02, and 4.00- resistors. (c) Calculate the equivalent resistance of the combined resistance found in part (b) and the parallel 3.00- resistor. (d) Combine the equivalent resistance found in part (c) with the 2.00- resistor. (e) Calculate the total current in the circuit. (f) What is the voltage drop across the 2.00- resis- tor? (g) Subtracting the result of part (f) from the battery volt- age, find the voltage across the 3.00- resistor. (h) Calculate the current in the 3.00- resistor. 10.0 Ω 2.00 Ω W 5.00 Ω w 8.00 V 4.000 w 3.00 Ω Figure P18.10

10. GP Consider the circuit shown in Figure P18.10. (a) Calcu- late the equivalent resistance of the 10.0-0 and 5.00- resis- tors connected in parallel. (b) Using the result of part (a), calculate the combined resistance of the 10.0-02, 5.00-02, and 4.00- resistors. (c) Calculate the equivalent resistance of the combined resistance found in part (b) and the parallel 3.00- resistor. (d) Combine the equivalent resistance found in part (c) with the 2.00- resistor. (e) Calculate the total current in the circuit. (f) What is the voltage drop across the 2.00- resis- tor? (g) Subtracting the result of part (f) from the battery volt- age, find the voltage across the 3.00- resistor. (h) Calculate the current in the 3.00- resistor. 10.0 Ω 2.00 Ω W 5.00 Ω w 8.00 V 4.000 w 3.00 Ω Figure P18.10

College Physics

10th Edition

ISBN:9781285737027

Author:Raymond A. Serway, Chris Vuille

Publisher:Raymond A. Serway, Chris Vuille

Chapter18: Direct-Current Circuits

Section: Chapter Questions

Problem 10P: Consider the circuit shown in Figure P18.10. (a) Calculate the equivalent resistance of the 10.0-...

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