Capctr05 20Ω Given: The capacitors have initial voltages as shown in the above circuit. Att-0, the switch is closed. equ e Calculate the final voltage, Vi has reached equilibrium the final voltage, V...
please double check answer. have submitted many times and gotten wrong 22 A 250 mH 10Ω 225mA) 10A Given: The inductors bave initial curents as showa in the above circuit. Att-o, the switch is opened. Resquired: Calculate the final curreut, I through the inductor on the left, the final curreI2 thugh the inductor ou the right, and the energy dissipated in the resistor, i.e.. WR. by the tie the system has reached equilibrium Solution 22 A 250 mH 10Ω 225mA)...
At a time the switch is closed in the circuit At a time the switch is closed in the circuit, the voltage across the paralleled capacitors is 50V and the voltage on the C3 capacitor is 40V (Figure 1) Take that C1 = 210 nF, C2-760 nF and C3 360 nF. 400 Ω +40 V- 0 Part A What percentage of the initial energy stored in the three capacitors is dissipated in the 24 kS2 resistor? Express your answer using...
The initial voltage across the capacitor is 0 V. At time t=0, the switch is closed a) What is the time constant for this circuit? b) What is the final voltage across the 50 capacitor? c) What is the expression for the voltage across the 50 capacitor? d) Sketch the waveform for . e) What is the maximum instantaneous current that will flow through the capacitor? f) When will the voltage reach 5.0 V?
9. For the given circuit, if the initial voltage across the capacitor is vc(0*) = 0, find an expression for the voltrage across the capacitor as a function of time and graph voltage versus time. R= 100 k2 w v=100 V uc) C = 0.01 uF 10. If a 100-F capacitance is initially charged to 1000V and at t=0, it is connected to a 1-ka resistance, at what time has 50 percent of the initial energy stored in the capacitance...
The switch in the circuit of Fig. P 7.55 has been in position a for a long time. At t- 0 the switch is moved to position b. Calculate (a) the initial voltage on the capacitor; (b) the final voltage on the capacitor; (c) the time constant (in microseconds) for t > 0; and (d) the length of time (in microseconds) required for the capacitor voltage to reach zero after the switch is moved to position b.