(b)Figure Q2(b) shows the time domain circuit with the voltage source, v,(t) is25 cos 100t V. The measured current flows through the 5 mF capacitor is io(t) =5 cos(100t + 90°) A.(i)Draw the circuit in phasor form.(ii)Show that the phasor I1 is 2.4 – j3.2 A.(iii)Determine the phasor V4. Compute the components that constitute X.30 mH(1)º:5 mF1Ω2 mFv.(t)+i,(1)vA(t)X10mF4ΩFigure Q2(b)

In an AC circuit all elements work on the same frequency. As the source of the circuit is connected…

(b) Figure Q2(b) shows the time domain circuit with the voltage source, vs(t) is 25 cos 100t V. The measured current flows through the 5 mF capacitor is io(t) = 5 cos(100t + 90°) A. %3D (i) Draw the circuit in phasor form. (ii) Show that the phasor I, is 2.4 – j3.2 A. (iii) Determine the phasor V4. Compute the components that constitute X.

(b) Figure Q2(b) shows the time domain circuit with the voltage source, vs(t) is 25 cos 100t V. The measured current flows through the 5 mF capacitor is io(t) = 5 cos(100t + 90°) A. %3D (i) Draw the circuit in phasor form. (ii) Show that the phasor I, is 2.4 – j3.2 A. (iii) Determine the phasor V4. Compute the components that constitute X.

Delmar's Standard Textbook Of Electricity

7th Edition

ISBN:9781337900348

Author:Stephen L. Herman

Publisher:Stephen L. Herman

Chapter21: Resistive-capacitive Series Circuits

Section: Chapter Questions

Problem 6RQ: A 15-F AC capacitor is connected in series with a 50 resistor. The capacitor has a voltage rating...

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