Find the equivalent impedance Zeq seen by the source when Vs = 6 cos (5t) v, C = 0.1 F, R = 1 §2 and L = 0.2 H.(Give angles in degrees and round final answers to two decimal places.)Calculate the voltage across each component - capacitor, resistor and inductor. (Give angles in degrees and round finalanswers to two decimal places.)VsRThe equivalent impedance seen by the source is 1±2% +j -1 ± 2% 2 = 1.41 ± 2% at an angle of -45 ± 2% 2.The voltage across the capacitor is 8.49 ± 2% at an angle of -45±2% v.The voltage across the resistor is 4.24 ± 2%The voltage across the inductor is 4.24 ± 2%at an angle of 45 ± 2% v.at an angle of 135±2% v.

In this question, we need to determine the total impedance, voltage across each elements. Inductive…

Find the equivalent impedance Zeq seen by the source when Vs = 6 cos (5t) v, C = 0.1 F, R = 12 and L = 0.2 H. (Give angles in degrees and round final answers to two decimal places.) Calculate the voltage across each component - capacitor, resistor and inductor. (Give angles in degrees and round fin answers to two decimal places.) Vs R The equivalent impedance seen by the source is 1±2% +j -1±2% 2 = 1.41 ± 2% at an angle of -45 ± 2% . The voltage across the capacitor is 8.49 ± 2% at an angle of -45 ± 2% v. The voltage across the resistor is 4.24 ± 2% at an angle of 45 ± 2% v. The voltage across the inductor is 4.24 ± 2% at an angle of 135 ± 2% v.

Find the equivalent impedance Zeq seen by the source when Vs = 6 cos (5t) v, C = 0.1 F, R = 12 and L = 0.2 H. (Give angles in degrees and round final answers to two decimal places.) Calculate the voltage across each component - capacitor, resistor and inductor. (Give angles in degrees and round fin answers to two decimal places.) Vs R The equivalent impedance seen by the source is 1±2% +j -1±2% 2 = 1.41 ± 2% at an angle of -45 ± 2% . The voltage across the capacitor is 8.49 ± 2% at an angle of -45 ± 2% v. The voltage across the resistor is 4.24 ± 2% at an angle of 45 ± 2% v. The voltage across the inductor is 4.24 ± 2% at an angle of 135 ± 2% v.

Power System Analysis and Design (MindTap Course List)

6th Edition

ISBN:9781305632134

Author:J. Duncan Glover, Thomas Overbye, Mulukutla S. Sarma

Publisher:J. Duncan Glover, Thomas Overbye, Mulukutla S. Sarma

Chapter2: Fundamentals

Section: Chapter Questions

Problem 2.7P: Let a 100V sinusoidal source be connected to a series combination of a 3 resistor, an 8 inductor,...

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