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as HOMEWORKLIB RULES rule,,i need to write only one question..please re-post the remaining question..thanks
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4. Find vx(t) in the time domain in the following circuit. (12 points) 0.005 F 100...
In the circuit below, i1 = -12 A, 12 = -15 A, and v1 = 11 V. Use nodal analysis to find Vx and iy in the circuit below 2 VX 60 + W W 2Ω + 50 5 VX 40 W + - il | ly v1 703 4iy 3Ω W + 2014 Paul Hummel cc o BY NG SA Vx= V ly = A
Help me solve these questions, please show work. Search 4:52 PM Wed Feb 12 78% A few sample problems from previous midterm 1 tests.pdf 1 of 4 Problem 1: (50 Points) In the following circuit, find V, by either Nodal Analysis Method or Loop Analysis Method. Clearly mark and/or identify, as needed, the nodes, the loops, the variables you assign, the constraint equations (if any), the super nodes and/or super meshes (if any), and the nodes for the KCL and...
You have the following circuit in sinusoidal steady-state. Use phasor circuit analysis to find the time domain expression for the steady-state current, i(t), and steady-state voltages, VR(t), VC(t) and VL(t). Vs(t) = 50 cos(1000t) Volts. Problem 1 (20 points) You have the following circuit in sinusoidal steady-state. Use phasor circuit analysis to find the time domain expression for the steady-state current, i(t), and steady- state voltages, Vr(t), Vc(t) and Vl(t). Vs(t) = 50 cos(1000t) Volts. i(t) 100 12 25 mH...
Problem (1) – 6 pts. Consider the circuit below with o=10 rad/sec: 10 mF 12 cos w V -о а 2 sin et A 1012 H ell 200 оь a) Find the Thevenin equivalent of the circuit in the frequency domain to the left of terminals a-b. Use Mesh Analysis to obtain V (No other method will be accepted.) Use the Nodal Analysis to obtain Z (No other method will be accepted.) b) Find the Norton equivalent of the given...
Problem 5. Use phasor techniques to analyze the circuit shown below and answer the following questions. a. Draw the frequency domain circuit b. Find the equivalent impedance C. Find the current iſt) flowing from left to right through the 30 ohm resistor d. Find the steady-state voltage v.(t) (Hint: answer is v.(t) = 17.14 cos(2000) V) 3022 5022 W 50 uF 60 sin 2001 V 0.1 H 3.0)
Use the following circuit diagram (10 points) The resistance between two points A and B is denoted by RAB RAB = 0.2 Ω; RBC = 0.2 Ω; RCD = 0.2 Ω; REF = 0.2 Ω; RFG = 0.1 Ω; RGH = 0.1 Ω; RHI = 0.2 Ω; RJK = 0.3 Ω; RKL = 0.3 Ω; The current between two points F and B is denoted by IFB IFB = 10 A; ICH = 4 A; IID = 8 A; IGK...
3) (20 points) For the circuit in figure below, find i(t) 30 12 cos(6t +30) A 16 0 i(t) 50 sin(2t) V
B. In the circuit in Figure -3, find the value of I, and v [4 Marks] In 4k22 3 mv 3 mV i 501, 20k1226 Figure 3 B. In the circuit shown at Figure -6, find the value of Vx due to the 5 A source. [2 marks) 100 a) 40 V b) 50 V c) 15 V d) 22 V = 12v $400 Figure 6
h(t) V(t) 5sin(2t 75°) +8 V V2) 10cos(2t30°) V Kt 2sin(5t-20) A i(t) Vx(t) AV(t) MW- R 100 R L 2H C1 0.1F V2(t) C2= 0.05F A 4 VAt) The circuit above is in steady state. Solve for i (t). (Hint: There are 3 different frequencies present in this network, so you must use superposition to find each source's contribution to i,(t) since the reactive elements will present different impedances based on which frequency you are considering. DO NOT add...
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