suppose Vs = 10 cos(10t) in the circuit below. Find L(t) in steady state. (R=10Ω ,...
Using the superposition principle, find the steady state current i(t) for the circuit shown. vs(t) = 10 cos 10t V, is = 3A. 5r 1.5H hu SIDDA vo 10 ME 10 mE 1023
For the circuit below, Vs(t) = 100 cos(100t + 56o) in steady-state. Using Node-Voltage, find steady-state expressions for VL(t) and iL(t). Also find the power factor at the load. ) Ika 25mH 5kos 15uF V2100mH 20 uF
8.51. Find the ac steady-state value of iL(t) 4 S2 2 52 22 100 cos 10t V 10 S2 2 H PROBLEM P8.51 00 T 8.51. Find the ac steady-state value of iL(t) 4 S2 2 52 22 100 cos 10t V 10 S2 2 H PROBLEM P8.51 00 T
If Vs(t) = 10 cos (10t - 90o) V, determine: brief description and legible formulas and variables Step 1: The voltage phasor VSF Step 2: The equivalent impedance Zeq Step 3: The phasor current IF Step 4: The steady state current I(t)ss Step 5: The complex power (S = ½VSFIF* = P + jQ). Step 6: The average (P) and reactive power (Q). Step 7: The power factor and sketch of the power triangle. Vs(t) (+) 0.1H Zeq If Vs(t)...
14. Problem For the circuit in figure below, find the steady-state output voltage vo (t). The input signal is v (t) and C = 5 μF 4-2 cos 100t, R 1 kΩ Do C R 12 U) 14. Problem For the circuit in figure below, find the steady-state output voltage vo (t). The input signal is v (t) and C = 5 μF 4-2 cos 100t, R 1 kΩ Do C R 12 U)
CLOSED OPEN Page 2 > of 6 ☺ Question 1: (a). The voltage vs(t)= 10 cos(10t +30°)V is applied to the inverting op amp as shown below. Using phasor, find (i) volt) 100 KS 2 (ii) v(t) 100 k92 20 k 2 M (iii) Zo (impedance) volt) Vs 20 k2 100 uFv 27 Zo 0 - FS 0 + F O FE F7 Home F8 BR F12 F10 F11 $ C ) % 5 * 00 3 - 7 9...
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...
For the circuit shown, find the steady-state voltage across the inductor v (t), when us 1 (t) = 20 cos(1000t) V, vs2(t) = 30 cos(1000t-90') V, using: (a) The mesh-current method (b) The node-voltage method. (c) The Source transformation Method (d) The superposition Principle (e The Thevenin's equivalent at the terminals a-b. 200μF VL 15mH Vs2 10Ω For the circuit shown, find the steady-state voltage across the inductor v (t), when us 1 (t) = 20 cos(1000t) V, vs2(t) =...
For the circuit shown, find the steady-state voltage across the inductor v (t), when us 1 (t) = 20 cos(1000t) V, vs2(t) = 30 cos(1000t-90') V, using: (a) The mesh-current method (b) The node-voltage method. (c) The Source transformation Method (d) The superposition Principle (e The Thevenin's equivalent at the terminals a-b. 200μF VL 15mH Vs2 10Ω For the circuit shown, find the steady-state voltage across the inductor v (t), when us 1 (t) = 20 cos(1000t) V, vs2(t) =...
Use the node-voltage method to find the steady-state expression for voft) in the circuit below if Vg1 20*cos(2000t - 36.879) V, Vg2 50*sin(2000t 16.269) V 100 μF 1 mH 0, 10Ω Vg2