2mF 20 Ω 2 H 7. Using methods of phasor analysis, for a sinusoidal driving frequency...
Problem 6)
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Problem 6 Part A ll Review | Constants I,n = 7 A f = 400 Hz , R1 = 2 Ω , R2 = 4 Ω , L1 = 10 mH The output current io(t) takes the form .,-100 mH . C1 = 30 mF , and C2 = 80 mF , in the circuit shown ie(t) Find Io 1, cos(2m400t +%) ,o View Available Hint(s) し2 図? Submit Rather than analyze this...
Problem 1: Find the input impedance for the following circuit. Assume an angular frequency of 0 = 50 rad/sec. 2 mF 200 mH Zin 10 mF T10mF Problem 2: Calculate average power absorbed by impedance Z = 30-7092 when a voltage V = 120 20° is applied across it. Problem 3: Assuming w=1, for the following circuit find: a. Input impedance ZH b. Thevenin voltage V c. The value of R, that will absorb the maximum average power (recall this...
18. The circuit of Figure P10.18 operates in the sinusoidal steady state at a frequency of (1), = 2000 rad/sec, R, = R, = 10 S2, V:,, = 50 V, and I. = 22 - 53.13º A. Compute the phasor volt- age across R2 and then find the impedance Z(w). Now construct a simple series circuit that represents this impedance at (1) N Figure P10.18 ANSWER: 2 = 2.5 + 710 12
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...
3.3) Consider the circuit shown in Figure Q3.3. With phasor approach, find Vo(t) using MESH analysis. [15M] 5Ω 102 2 sin 1000t 152 20 MF Vot) ell 10 mH Figure Q3.3
d) If a capacitor has an impedance of-j4 Ω in a circuit operating at a frequency 012 rad/s, what is the value of its capacitance? A) C= 8.17 mF c) c" 4.32 mF D) C- 12.5 mF two parallel elements have to be the same. A) True B) Faise f The sum of voltages around a closed loop are equal to zero volts. A) True B) False g) Kirchhoff's Current Law at node Ve in Circuit 4 can be written...
(a) For the circuit of Figure 4, assuming a sinusoidal is(t) (0) Prove that the resonant frequeney is given by o- (3 marks) LC (ii) If the total admittance at resonance is 20 ms (seen by the source) with resonant frequency of wo 5000 rad/s and quality factor of Q-10, calculate the values of R L, C, the bandwidth and half-power frequencies in Hertz. (4 marks) VG and hence show (iii) Derive an expression for the driving point impedance Z(jø)...
Question #01 (30 points) Consider the following circuit. Let us define the phasors in terms of the Sine function. 0.25 F 12 H 222 1H = 0.5 F {52 8 sin (2t + 30°) V Zeq + 1. Draw phasor domain circuit. (4 points) 2. Find Zee for the circuit as seen from input voltage source. (6 points) 3. Draw Zeq phasor. (2 points) 4. Find resistance and reactance for Zeq. Is the reactance capacitive or inductive? (3 points) 5....
Question 2 (20 points) Consider the circuit below with Vị as the input and v, as the output. Let the component values be R = 33.2, C = 470uF and L = 250mH. R + + yo(t) L - Answer the following questions using the formulas from the lecture slides: 1. What is the type of this filter? (2 points) 2. Write down the expression for the transfer function H(w) of the circuit. (4 points) 3. Write down the expression...
4. (10.6) Find the output voltage (as a phasor) in the circuit below. j1 Ω 2Ω W 2020° 192 5/20 5. (10.42) Find the currents and voltages (as phasors) in the circuit below containing an ideal transformer. WW th ot 20 7602 20200 & 10 6. (10.43) Find the voltage (as phasor) in the circuit below containing an ideal transformer. 2:1 2:1 rün 402 W W of 22 2020 -120 lllll j622 lo 7. If Li - 30 mH, L2...