10. Find Vo in the circuit in Fig. P5.38 using Thévenin's theorem. 12 V Figure P5.38
Apply Thévenin's theorem twice to find Vo in the circuit in the figure below. Chapter 8, Problem 8.126 Apply Thévenin's theorem twice to find Vo in the circuit in the figure below. 1Ω 2Ω ΙΩ 20Ω a Find the real part of V (b) Find the imaginary part of vo Chapter 8, Problem 8.126 Apply Thévenin's theorem twice to find Vo in the circuit in the figure below. 1Ω 2Ω ΙΩ 20Ω a Find the real part of V (b)...
use thevenins theorem 5.62 In the network in Fig. P5.62, find V, using Thévenin's theorem. 12 V 1ke w to 5v.<$ 250 kn oi of Figure P5.62
Use Thévenin's theorem to find Vo in the circuit in the figure below. Break the network just to the right of the vertical 5k Ohm resistor containing Ix 5 V 9 fx fx Rm= Vo -
Chapter 5, Problem 5.068 Use Thévenin's theorem to find Vo in the circuit in the figure below. Break the network just to the right of the vertical 6k Ohm resistor containing Ix 6 V 7 kO 7 Ix 4 ko 2 kn 6 kO VTh V RTh k2 Vo II
Chapter 5, Problem 5.068 Use Thévenin's theorem to find V. in the circuit in the figure below. Break the network just to the right of the vertical 7k Ohm resistor containing Ix. 7 ko 3k 6 x 6ko 7ko v. Vth = Rth = Vo =
Chapter 5, Problem 5.068 Use Thévenin's theorem to find V. in the circuit in the figure below. Break the network just to the right of the vertical 5k Ohm resistor containing Ix. 5V - 2 ko 2 x 7ko 5ko 9ko V. Vth Rth = Vo = Click if you would like to Show Work for this question: Open Show Work
P7. Use Thévenin's theorem to find the power supplied by the 12-V source in circuit below: 2 mA 32 1 kS2 12 V
Problem 33: Solve for Vo by using Thévenin's theorem. 262 2k2 M w 0 + 12V 12mA $4k2 Zo Answer: Vo = 8 V Problem 34: Use Thévenin's theorem to solve for Vo. 3k2 WW Gk2} 3kh 4mA (V) 12V @ 12V + Answer: Vo=-12 V
19. Using Thévenin's theorem, determine the effective voltage and the effective resistance of the circuit in Figure F with R5 removed R,-100 Ω R, 1000 Ω R, 99 Ω RS: 10 Ω V 10 V 4 FIGURE F Circuit for problems 19, 20, 21 and 22. 20. What is the current through R, of the circuit of Figure F?
Find V. in the network in the figure below using Thévenin's theorem. Break the network just to the right of the dependent source, i.e. separate the current source and two resistors on the right from the rest of the network. 2ko 5000 1x zko 6v 7 kg 2 mA 2ko V.