In the circuit shown in Figure 10.20, find the Thévenin equivalentvoltage Vth and the Thévenin equivalent impedance Zth betweenterminals a and b.ZLj9 27320⁰ VR₁12 02R₂602Figure 10.20O a. Vth = 41.72-j35.04 V, Zth = 8.32 + j5.76 02O b. Vth = 46.72-j35.04 V, Zth = 10.32 + j5.76 02O c. Vth = 51.72-j35.04 V, Zth = 12.32 +j5.76O d. Vth = 56.72-j35.04 V, Zth = 14.32 + j5.76 2

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In the circuit shown in Figure 10.20, find the Thévenin equivalent voltage Vth and the Thévenin equivalent impedance Zth between terminals a and b. Z j9 92 7320⁰ V R₁ 12 Ω R₂ 652 Figure 10.20 O a. Vth = 41.72-j35.04 V, Zth = 8.32 + j5.76 O b. Vth = 46.72-j35.04 V, Zth = 10.32 +j5.76 02 O c. Vth=51.72-j35.04 V, Zth = 12.32 +j5.76 02 O d. Vth = 56.72-j35.04 V, Zth = 14.32 + j5.76 2 D

In the circuit shown in Figure 10.20, find the Thévenin equivalent voltage Vth and the Thévenin equivalent impedance Zth between terminals a and b. Z j9 92 7320⁰ V R₁ 12 Ω R₂ 652 Figure 10.20 O a. Vth = 41.72-j35.04 V, Zth = 8.32 + j5.76 O b. Vth = 46.72-j35.04 V, Zth = 10.32 +j5.76 02 O c. Vth=51.72-j35.04 V, Zth = 12.32 +j5.76 02 O d. Vth = 56.72-j35.04 V, Zth = 14.32 + j5.76 2 D

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 2.1MCQ: The rms value of v(t)=Vmaxcos(t+) is given by a. Vmax b. Vmax/2 c. 2Vmax d. 2Vmax

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