Using V = 14 mV, and given the voltage across an inductor L = 2 mH as shown in Fig.P6.25, determine the equation of current as a function of time across the inductorduring the time Oms <= t <= 1 ms. Assuming the solution looks like i₁(t) = Xt² + C,what is the value of X? For your answer, just put the value of X in Amperes/s² (thereshould only be a number in your answer).v(t) (mV) 4V-t (ms)

Answered: Image /qna-images/answer/5efe614f-b02b-4cae-97f7-b10eb1c42b13.jpg

Using V = 14 mV, and given the voltage across an inductor L = 2 mH as shown in Fig. P6.25, determine the equation of current as a function of time across the inductor during the time 0ms <= t <= 1 ms. Assuming the solution looks like iL(t) = Xt² + C, what is the value of X? For your answer, just put the value of X in Amperes/s² (there should only be a number in your answer). v(t) (mV) 4 V t (ms)

Using V = 14 mV, and given the voltage across an inductor L = 2 mH as shown in Fig. P6.25, determine the equation of current as a function of time across the inductor during the time 0ms <= t <= 1 ms. Assuming the solution looks like iL(t) = Xt² + C, what is the value of X? For your answer, just put the value of X in Amperes/s² (there should only be a number in your answer). v(t) (mV) 4 V t (ms)

Introductory Circuit Analysis (13th Edition)

13th Edition

ISBN:9780133923605

Author:Robert L. Boylestad

Publisher:Robert L. Boylestad

Chapter1: Introduction

Section: Chapter Questions

Problem 1P: Visit your local library (at school or home) and describe the extent to which it provides literature...

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