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2. The circuit shown in Fig. 2 is given in the time domain. a. Draw the...
Problem 5. Use phasor techniques to analyze the circuit shown below and answer the following questions....
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)
For the time-domain circuit shown in Fig. 2 the switch is closed at t = 0....
For the time-domain circuit shown in Fig. 2 the switch is closed
at t = 0.
a. Draw the equivalent circuit in s-domain.
b. Write a pair of simultaneous s-domain mesh current
equations.
2A * 4H 0.2 F 14v 149) 0.25 F 10 V izle G Fig. 2
For the circuit shown in Fig. 4.1, there is no initial energy storage. Draw and label...
For the circuit shown in Fig. 4.1, there is no initial energy storage. Draw and label the circuit in the s domain and use it to determine H(s)=Vo(s)/Vsrc(s). Using H(s) and given: (a) vsrc(t)= e'u(t) V, find vo(t) using the inverse Laplace Transforms. (b) vsrc(t)=2 cos 2t V, determine the steady state output vo(t). + 0.50, 1H 192 w + + + USRC 1 F V, 212 vo
Problem 4.1 For the circuit shown in Fig. 4.1, there is no initial energy storage. Draw...
Problem 4.1 For the circuit shown in Fig. 4.1, there is no initial energy storage. Draw and label the circuit in the s- domain and use it to determine H(s)=V_(s)/Vsrc(s). Using H(s) and given: (a) vsrc(t)= e'u(t) V, find vo(t) using the inverse Laplace Transforms. (b) vsrc(t)=2 cos 2t V, determine the steady state output volt). 0.502 122 1н + USRC 1 F V, 22 VO Fig. 4.1
6.4 (5) Draw the frequency domain circuit and calculate v(t) for the circuit shown if i(t)-10...
6.4 (5) Draw the frequency domain circuit and calculate v(t) for the circuit shown if i(t)-10 sin(1000t -30°) A 35 Ω i(t) v(t) 15 mH 6.5 (5) Calculate the three phasor currents Ic, IR and It. from problem 6.4 and draw them on a phasor diagram. Show both algebraically and on the phasor diagram that: I=Ic + IR + IL
For the circuit shown below. Ifv.(t) = 100 cos(2001+30) V and vy(t) = 50 cos(2000) V....
For the circuit shown below. Ifv.(t) = 100 cos(2001+30) V and vy(t) = 50 cos(2000) V. a) Redraw the circuit using Phasor equivalent. b) In the Phasor domain, find the node voltage equations. 1 mF 20 ml 30 000 30 mH 0.25 mF
6. (20) Transform the circuit below to phasor domain. Sketch and completely label the transformed circuit....
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
QUESTION 5 Draw the equivalent simple circuit model for the circuit shown. Calculate V, I, and...
QUESTION 5 Draw the equivalent simple circuit model for the circuit shown. Calculate V, I, and R for the simple circuit model that are equivalent to the original circuit. Include units, prefixes, and polarities (where applicable). Indicate current direction on your simple circuit model with an arrow. 1kΩ 2kΩ 1kΩ 4kΩ w 1kΩ 3kΩ 12V 3k2 4kΩ + 3V -
5. Shown here is the time-domain depiction of a circuit containing an ideal OpAmp. a) Sketch...
5. Shown here is the time-domain depiction of a circuit containing an ideal OpAmp. a) Sketch the corresponding phasor domain circuit assuming that vę (t) = V cos(ot+0). NVcci b) Derive the phasor domain expression for the output voltage phasor, V. TO -Vcci c) Determine the time domain output voltage, v. (t).
2- A circuit across the terminals of a sinusoidal voltage source, as shown in Figure 2....
2- A circuit across the terminals of a sinusoidal voltage source, as shown in Figure 2. The steady-state expression for the source voltage is v;=50.cos(1000t+20). (40 points) 12 mH 100 MF 10 Figure 2 a) Construct the frequency-domain equivalent circuit. b) Calculate the steady-state current i by the phasor method.
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)
For the time-domain circuit shown in Fig. 2 the switch is closed
at t = 0.
a. Draw the equivalent circuit in s-domain.
b. Write a pair of simultaneous s-domain mesh current
equations.
2A * 4H 0.2 F 14v 149) 0.25 F 10 V izle G Fig. 2
For the circuit shown in Fig. 4.1, there is no initial energy storage. Draw and label the circuit in the s domain and use it to determine H(s)=Vo(s)/Vsrc(s). Using H(s) and given: (a) vsrc(t)= e'u(t) V, find vo(t) using the inverse Laplace Transforms. (b) vsrc(t)=2 cos 2t V, determine the steady state output vo(t). + 0.50, 1H 192 w + + + USRC 1 F V, 212 vo
Problem 4.1 For the circuit shown in Fig. 4.1, there is no initial energy storage. Draw and label the circuit in the s- domain and use it to determine H(s)=V_(s)/Vsrc(s). Using H(s) and given: (a) vsrc(t)= e'u(t) V, find vo(t) using the inverse Laplace Transforms. (b) vsrc(t)=2 cos 2t V, determine the steady state output volt). 0.502 122 1н + USRC 1 F V, 22 VO Fig. 4.1
6.4 (5) Draw the frequency domain circuit and calculate v(t) for the circuit shown if i(t)-10 sin(1000t -30°) A 35 Ω i(t) v(t) 15 mH 6.5 (5) Calculate the three phasor currents Ic, IR and It. from problem 6.4 and draw them on a phasor diagram. Show both algebraically and on the phasor diagram that: I=Ic + IR + IL
For the circuit shown below. Ifv.(t) = 100 cos(2001+30) V and vy(t) = 50 cos(2000) V. a) Redraw the circuit using Phasor equivalent. b) In the Phasor domain, find the node voltage equations. 1 mF 20 ml 30 000 30 mH 0.25 mF
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
QUESTION 5 Draw the equivalent simple circuit model for the circuit shown. Calculate V, I, and R for the simple circuit model that are equivalent to the original circuit. Include units, prefixes, and polarities (where applicable). Indicate current direction on your simple circuit model with an arrow. 1kΩ 2kΩ 1kΩ 4kΩ w 1kΩ 3kΩ 12V 3k2 4kΩ + 3V -
5. Shown here is the time-domain depiction of a circuit containing an ideal OpAmp. a) Sketch the corresponding phasor domain circuit assuming that vę (t) = V cos(ot+0). NVcci b) Derive the phasor domain expression for the output voltage phasor, V. TO -Vcci c) Determine the time domain output voltage, v. (t).
2- A circuit across the terminals of a sinusoidal voltage source, as shown in Figure 2. The steady-state expression for the source voltage is v;=50.cos(1000t+20). (40 points) 12 mH 100 MF 10 Figure 2 a) Construct the frequency-domain equivalent circuit. b) Calculate the steady-state current i by the phasor method.
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