Problem 1: For the circuit below, use TIME DOMAIN TECHNIQUES. a) Find v, i, and the...
2. For the circuit in problem 1 above: a) Transform the circuit into the s-domain b) Using Laplace transform techniques applied directly to the circuit (not applied to the differential equation found in problem 1), find iz(t), t > 0. No credit for time- domain techniques. IX V 40 + - 5+10u(t) 10 H 1/4 F 2. For the circuit in problem 1 above: a) Transform the circuit into the s-domain b) Using Laplace transform techniques applied directly to the...
Problem 1: /25 For the circuit shown below, use frequency-domain circuit analysis techniques to determine (a) the voltage transfer function Ho) of the circuit; (b) the magnitude response H(o) of the circuit; and (c) the phase response (0) of the circuit. (d) Based on the results of parts (a) - (c), identify the type of filter circuit shown. R + Vin(t) llll L Vout(t)
Problem 4: /25 For the circuit shown below, use frequency-domain circuit analysis techniques to determine (a) the voltage transfer function Hw) of the circuit; (b) the magnitude response H(o) of the circuit; and (c) the phase response (0) of the circuit. (d) Based on the results of parts (a) - (c), identify the type of filter circuit shown. R L 10000 + + Vout(t)
Problem 2: /25 For the circuit shown below, use frequency-domain circuit analysis techniques to determine (a) the voltage transfer function H(o) of the circuit; (b) the magnitude response H(o) of the circuit; and (c) the phase response (0) of the circuit. (d) Based on the results of parts (a) - (c), identify the type of filter circuit shown. L 10000 + + R Vout(t)
Problem 3: /25 For the circuit shown below, use frequency-domain circuit analysis techniques to determine (a) the voltage transfer function Ho) of the circuit; (b) the magnitude response H(@) of the circuit; and (c) the phase response (0) of the circuit. (d) Based on the results of parts (a) - (c), identify the type of filter circuit shown. с R + + Vin(t) 0000 L Vout(t)
Transform the circuit below into the frequency domain, then use nodal analysis to find V(ω), the Fourier transform of v(t). 212 www + + 1 V v(t) 1F 28(t) A
6. (20) Transform the circuit below to phasor domain. Sketch and completely label the transformed circuit. Find the steady state value of i(t). (Hint: Find the current (I) in the phasor domain then convert it back to the time domain to find i(t).) 15 F 375mH 30 cos (377t-15°) V
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)
TASK (i): Find time-domain equations for a parallel LC resonant circuit An LC resonant circuit is sometimes referred to as an LC-tank or tuned circuit. It is made up of two components: an inductor (L) and a capacitor (C), hence the name. CAPACITOR 4 e V - + V - Figure 1: Capacitor symbol The charge on a capacitor is proportional to the voltage across it, the constant of proportionality being the capacitance C, measured in Farads (F). Since current...
this is the v(t) -157-63 a li 1.17 +구-1-245 e + 0.071, e (e) Plot the voltage response v(t) in the time domain using MATLAB. Plot v(c) over the specified time interval using a blue solid line of width lines of width 2. The minimum font size is 16. i. i. Plot the capacitor's voltage rating threshold as horizontal black dashed i. Label both axes with the appropriate physical quantity as well as units. iv. The minimum font size for...