In the circuit shown below the current source has been switched on for a very long time. Find the DC current in the inductor and the DC voltage across the capacitor.
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In the circuit shown below the current source has been switched on for a very long...
In the circuit shown below, calculate the current through each diode. Use the ideal diode model. You must submit answer(s) to the exam question before other options can be enabled. Enter your answers in the text boxes and click on the Submit button. Please DO NOT USE THE BROWSER'S NAVIGATION BUTTONS (Back and Forward) in the Exam mode; it may lead to unpredictable results. To get a perfect score (100), the accuracy ofyour answer(s) must be 1% or better. Submit...
Problem 4 In the circuit shown below, the switch has been opened for a very long time prior to t= 0 and closes at t = 0 and remains closed for a long time. Please find: a) i (0), vc(ot), b) the steady-state voltage across the capacitor in terms of Us, Rı, and R2 c) the steady state current through the inductor in terms of Us, Ry, and R2 d) Write the differential equation for it) in terms of Vs,...
The switch in the circuit below has been closed for a very long
time. 2.
a. What is the voltage across the capacitor?
b. If the switch is opened, what is the time constant for
discharging the capacitor?
c. how long does it take the capacitor to discharge to 1/10th of
its initial voltage?
R1 = 1.00 Ω
R2 = 8.00 Ω
R3 = 4.00 Ω
R4 = 2.00 Ω
C = 1.00 μF
Battery = 10.0 V
R2 R4
Find the node voltages in the circuit shown below. Enter your solution below: lc R2 R3 37 R1 17 41 Ben Rodanski Version 6.0
(1) In the system shown below, the input is the ideal current source *i,' is and the output is the voltage across the inductor L1I'. Derive the governing differential equations for the circuit shown below and represent them in state space form. 41-K The state variable R2 L1 R3 Vc C1
Consider the series RLC circuit in Figure 1. Suppose the source voltage is initially OV, and no energy is stored in both the capacitor and inductor. At t = 0, the source voltage is switched to 1V. Calculate the resistor, inductor and capacitor voltages, and the loop current V (t),,(t),Vc(t),i(t). Show all the steps. C1 L1 1.2u 8.2m 10 3 R1 Figure 1: A series RLC circuit
I can find iL(0+) and
vC(0+), but I cannot find tm and
Vcm. The final answer is given for Vcm=-4.718 V and tm=1.7018
ms
In the circuit shown below, the switch was open for a very long time and closes at t = 0. Calculate: 1. The initial value of inductor current, IL(0*), 2. The initial value of capacitor voltage, vc(0*), 3. The minimum value of the capacitor voltage, Vcm, 4. The time, tm, when the minimum in p.3 occurs....
3. Consider the AC circuit shown in the figure below, consisting
of an alternating voltage source—of voltage V (t) = V0 cos (ωt)—a
capacitor (of capacitance C), an inductor (of inductance L), and
two resistors (of resistances R1 and R2). Also, note the
highlighted points a and b in the circuit. (a) While explaining
your reasoning, determine the necessary condition that must be
satisfied between the circuit elements such that the potential
difference between points a and b is zero...
1) In the circuit below the currents are named A, and lc The current direction is determined by the source (out of positive terminal) in the middle and right branches and is clockwise in the left branch · IA flows through R2 and R1 Is flows through R4 and Vb cflows through R3, Vc AB R2 R3 R4 R1 Vb a) Draw the circuit and show the 3 currents described above, including arrows showing the current direction. Show the voltage...
Consider the series RLC circuit in Figure 1. Suppose the source voltage is initially OV, and no energy is stored in both the capacitor and inductor. At t = 0, the source voltage is switched to 1V. Calculate the resistor, inductor and capacitor voltages, and the loop current VROV.O.Vc),it). Show all the steps. SOL L1 n 8.2m 10 3 R1 Figure 1: A series RLC circuit