plz show all steps Problem 2. (20 points) For the circuit shown below, 5v 102 15...
problem 2 please Problem 2 (50 points) Consider the circuit below and answer the following questions: R,-4Ω +Vi 2 V a- [20 Points] Using nodal analysis method, find the voltages VA. VB. Ve and Vo b [12 Points] Calculate the currents I and Is. c- 8 Points] Calculate the voltage Vs across the dependent current source. d- [10 Points] Calculate the power absorbed delivered by each voltage source in the circuit
Problem 3 [201 Calculate land power dissipated by 5 K Ω resistor for the amplifier (ideal) 10 ΚΩ 1ov 5V Problem 4 Find lo at steady state condition. Use Mesh analysis ·[20] Problem 5 Find Vo and I through it in the circuit circuit below (use 120] analysis) Nodal 50 Ω 5052 o.1 H "40 sin 200,丶- Problem 3 [201 Calculate land power dissipated by 5 K Ω resistor for the amplifier (ideal) 10 ΚΩ 1ov 5V Problem 4 Find...
Problem 03.020 Nodal analysis: Independent voltage source and current dependent voltage source In the circuit given below, R-25 ?. Find v1, v2, and v3 using nodal analysis. 240 V 20i 20 ? 3 li 40? ": 10? The value of vy in the circuit is The value of v2 in the circuit is| |V The value of vy in the circuit isv V.
current controlled voltage source 2i R2 V3 EV1 V2 R1 In the circuit above V1 = 86V,V2=96 V, 11-7AR1:39 ? and R2 : 35 ?. Use nodal analysis to find the voltage at node A in the circuit above. Note the presence of a dependent voltage source V3 Voltage across that source is 2i. i is the current through the resistor R2 and the source V2
Problem #7) Perform a steady-state AC phasor analysis of the circuit shown below in order to determine the RMS phasor values of the source current I, and the resistor voltage V, as shown in the figure, along with the value of the reactive power Qs produced by the voltage source: He v(t)=2.277-sin(0-t) 0=27. f ſ 60F f = 60 Hz vo 210 mH3 son Qs - - VARS
Please show all of the steps Question 2: 20% We can use stack of diodes as a voltage regulator as shown in the circuit below. Consider input voltage to this circuit as 20V DC with IV of fluctuation. Diodes in this circuit have 0.7V forward voltage drop a) What is DC output voltage Vo? 20+1V Vo= 1.4 V R=1k2 b) What is diode DC current lo? Ip= 18-6 ma c) What is the value of individual diode's small-signal resistor/? (4%)...
2. (2000) Electromagnetics (DC Circuit) Problem a. Calculate the voltages across all resistors and the currents through all the resistors and voltage sources in the following circuit using Kirchhoff's junction rule (nodal analysis). Show the directions initially assumed for the junction (node) currents. Use the minimum number of junctions (nodes) necessary to accomplish this b. Calculate the power dissipation in each resistor and the sum (or total) of these individual power dissipation values c. Calculate the power associated with each...
as small as you can Problem 3 (20 points) For the current divider circuit in Figure 3, calculate: a) lo and V. (10 points). b) The power dissipated in the 10 A resistor. (5 points). c) The power developed by the current source. (5 points). R3 200 VO Vo SR1 R5 3100 SA 10] 3300 3100 R2 N 200 Figure 3
7.2Ω 6Ω 2) For the circuit shown, find (a) the voltage Vo; (b) the power delivered to the circuit by the current source; and (c) the power dissipated in the 10Ω resistor. Vo 300 64Ω 10Ω
2) For the circuit shown, draw the phasor equivalent circuit for the described circuit, and answer the questions below. then find the voltage across the current source (v(t)). Note for questions b and c you need to determine the instantaneous power associated with the source using values for P and Q(P and Q are determined from the phasor analysis results for V and Ig) and then use the trig identity Acos(x)Bsin(x) = V42 + B2 cos(x-Tan(B/A to convert Pcos(x) -...