R4 11(t) SW1 SW2 Figure 1 The circuit in Figure 1 has been left for a...
SW1 t=0 6uF Given the capacitor circuit, assume SW1 has been closed and SW2 open for a long time. The capacitors C1, C2, C3 are fully charged and C4 is completely uncharged. | 04 4uF C3 3.6uF J C2 - 10 V Auf At t=0, SW1 is opened and sw2 is closed. SW2 For t<0 6. Find the equivalent capacitance between terminals A and B fort<0 7. Find the energy stored in the equivalent capacitor before for t<0 8. Find...
Consider the circuit depicted in Fig. 2. The switch SW1 has been closed for a long time before it is opened at time t = 0. The switch SW2 has been open for a long time before it is closed att = 0.1 (sec). i) Find the initial current I(0) flowing in the inductor and the initial voltage V(0) across the capacitor. ii) Find the voltage V(t) across the capacitor and the current I(t) through the inductor for 0 ≤ t ≤...
do not use s domain method ,use only differential equation
3. In the circuit shown, switch 1 has been closed for a long time before it is opened at t 0, and switch 2 has been opened for a long time before it is closed at t = 0. SW2 sw, 0.5Ω R2 1(2 A, 20 A i(t) 0.5 H a. Find the initial voltage v(O)- Vo across the capacitor and initial current through the inductor (0) lo at t...
In this RC circuit, at t = 0 second, switch 1 is closed, switch
2 is left opened.
a. Determine the current through the uncharged capacitor and the
2 resistors at t = 0 second. (1.33 A)
b. Determine the current through the capacitor and the 2
resistors at t = 100 µs. (0.35 A)
c. For this part, switch 1 is left opened and switch 2 is closed
after the capacitor was charged for a very long time (assume...
Please do the problem if you can do ALL parts.
t-0 a SW1 SW2 0.5 Ω 2 1Ω V. R3 20 A T v(t) 0.5 F 0.5 H 0 Find the initial current i(0) through the inductor and the initial voltage v(0) across the capacitor at t 0. b. Write a node equation at node a fort2 0. c. Represent v(t) as a function of i(t) on the series connection of R2 and L. Find dv(t)/dt. Derive a second-order differential...
Ri Sw Sw2R (a) Circuit Swi Closed + Open T t (ms) 10 20 30 40 50 Sw2 Closed (ms) 10 20 30 40 50 Figure m5.3 Voltage waveform for Problem m5.3. m5.3 Response of the RC Circuit: Figure m5.3(a) shows a resistor-capacitor circuit with a pair of switches and Fig. m5.3(b) shows the switch opening-closing behavior a function of time. The initial capacitor voltage is as -9 V. Component values are R1-10k. R2-3.3 kg2. (a) Determine the equation that...
The switch in the circuit in (Figure 1) has been in the left position for a long time. At t = 0, it moves to the right position and stays there. Part A Select the correct expression for the capacitor voltage, v(t), fort t ≥ 0Part B Select the correct expression for the current through the 24 kΩ resistor i(t) ≥ 0+.
The switch in the circuit in (Figure 1) has been in the left position for a long time Att 0, it moves to the right position and stays there 2.4 kΩ Part A Select the correct expression for the capacitor voltage, v(t), for t 0 (t) 240e-500t y (t) 240e-1000 v O r(t)-59.4e-1000e V v(t)59.4e-00 V (t) 80e-50 V (t)-80e-1000t V Part B: Select the correct expression for the current through the 2.4 kΩ resistor, i (t), for t >...
The switch in the circuit has been closed for a long time and is opened at t = 0. a. Calculate the initial value of I b. Calculate the initial energy stored in the inductor. c. What is the time constant of the circuit for t ≥ 0? d. What is the numerical expression for i() for t20? e. What percentage of the initial energy stored has been dissipated in the 4 Ω resistor 5ms after the switch has been opened?
The switch in the circuit shown has been closed for a long time and is opened at t = 0. Find a) The initial value of v(t), b) The time constant for t>0. c) The numerical expression for v(t) after the switch has been opened, d) The initial energy stored in the capacitor, and e) The length of time required to dissipate 75% of the initially stored energy.