The following questions refer to the circuit represented by the diagram atright. Think of R2 as the internal resistance of the inductor.a) Immediately after the switch is closed, find the magnitude and direction of the conventional current (if any) through the battery, and find the potential difference across the inductor.b) A long time after the switch is closed, find the magnitude and direction of the conventional current (if any) through the battery, and find the potential difference across the inductor.c) After the switch has been closed for a long time it is suddenly opened. Immediately after the switch is opened, find the magnitude and direction of the conventional current (if any) through the resistor R1 and the potential difference across the inductor. ** 18. The following questions refer to the circuit represented by the diagram atright. Think of R, as the internal resistance of the inductor.R2 = 50 Na) Immediately after the switch is closed, find the magnitude and directionof the conventional current (if any) through the battery, and find the potentialSwitchdifference across the inductor.b) A long time after the switch is closed, find the magnitude and direction ofthe conventional current (if any) through the battery, and find the potentialR = 50 NV = 200L = 20 H%3Ddifference across the inductor.c) After the switch has been closed for a long time it is suddenly opened. Immediatelyafter the switch is opened, find the magnitude and direction of the conventional current(if any) through the resistor R, and the potential difference across the inductor.

According to the question we have to calculate, a) Immediately after the switch is closed,…

** 18. The following questions refer to the circuit represented by the diagram at right. Think of R, as the internal resistance of the inductor. R, = 50 N a) Immediately after the switch is closed, find the magnitude and direction of the conventional current (if any) through the battery, and find the potential Switch difference across the inductor. b) A long time after the switch is closed, find the magnitude and direction of the conventional current (if any) through the battery, and find the potential R, = 50 N V = 200 L = 20 H difference across the inductor. c) After the switch has been closed for a long time it is suddenly opened. Immediately after the switch is opened, find the magnitude and direction of the conventional current (if any) through the resistor R, and the potential difference across the inductor. ww.

** 18. The following questions refer to the circuit represented by the diagram at right. Think of R, as the internal resistance of the inductor. R, = 50 N a) Immediately after the switch is closed, find the magnitude and direction of the conventional current (if any) through the battery, and find the potential Switch difference across the inductor. b) A long time after the switch is closed, find the magnitude and direction of the conventional current (if any) through the battery, and find the potential R, = 50 N V = 200 L = 20 H difference across the inductor. c) After the switch has been closed for a long time it is suddenly opened. Immediately after the switch is opened, find the magnitude and direction of the conventional current (if any) through the resistor R, and the potential difference across the inductor. ww.

Delmar's Standard Textbook Of Electricity

7th Edition

ISBN:9781337900348

Author:Stephen L. Herman

Publisher:Stephen L. Herman

Chapter17: Resistive-inductive Series Circuits

Section: Chapter Questions

Problem 2PA: You are a journeyman electrician working in an industrial plant. Your task is to connect an inductor...

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