500 2µF 10 mH 100n 10000 s + 5.10 + 15000 s + 5.107 a) H(s) = R = 50 A, R2 = 100 N, L = 10 mH,C = 2 µF, i,t) = 60 cos(10000€) mA 100 s? + 5.10° s g? + 15000 s + 5.10 b) H(s) = () = 60 cos (1000ot) mA V,) Sinusoidal current source Voltage on sinusoidal current source 5.105 s + 25.10" + 15000 s + 5.107 c) H(s) = Voltage on capacitor Current _passing through the capacitor _ Inductance voltage Current flowing from inductance Voltage over resistance R1 = 50 Voltage over resistance R2 = 100 [v.(() 5000 s + 15000 s + 5.107 d) H(s) = _Vr, (D), _Vr, (0 100 s + 10°s + 25.10" Va, (8) 1((s) e) H(s): H(s) = s2 + 15000 s + 5.10? which of the following is the transfer function?

500 2µF 10 mH 100n 10000 s + 5.10 + 15000 s + 5.107 a) H(s) = R = 50 A, R2 = 100 N, L = 10 mH,C = 2 µF, i,t) = 60 cos(10000€) mA 100 s? + 5.10° s g? + 15000 s + 5.10 b) H(s) = () = 60 cos (1000ot) mA V,) Sinusoidal current source Voltage on sinusoidal current source 5.105 s + 25.10" + 15000 s + 5.107 c) H(s) = Voltage on capacitor Current _passing through the capacitor _ Inductance voltage Current flowing from inductance Voltage over resistance R1 = 50 Voltage over resistance R2 = 100 [v.(() 5000 s + 15000 s + 5.107 d) H(s) = _Vr, (D), _Vr, (0 100 s + 10°s + 25.10" Va, (8) 1((s) e) H(s): H(s) = s2 + 15000 s + 5.10? which of the following is the transfer function?

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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