For the following LRC circuit with periodic electric source v(t), find the steady-periodic current in the...

Find the charge on the capacitor in an LRC-series circuit at t = 0.02 swhen L...

Find the charge on the capacitor in an LRC-series circuit at t = 0.02 swhen L = 0.05 h, R = 3 Ω, C = 0.02 f, E(t) = 0 V, q(0) = 2 C and i(0) = 0 A.(Round your answer to four decimal places.) C Determine the first time at which the charge on the capacitor is equal to zero. (Round your answer to four decimal places.) s

Find the charge on the capacitor in an LRC-series circuit at t = 0.02 s when...

Find the charge on the capacitor in an LRC-series circuit at t = 0.02 s when L = 0.05 h, R = 3 Ω, C = 0.008 f, E(t) = 0 V, q(0) = 3 C, and i(0) = 0 A. (Round your answer to four decimal places.)-Determine the first time at which the charge on the capacitor is equal to zero. (Round your answer to four decimal places.)

Voltage V = V0sin (ωt) is applied to the LRC series circuit, where V0 = 0.85...

Voltage V = V0sin (ωt) is applied to the LRC series circuit, where V0 = 0.85 V, ω = 7541 (1/s) and t is the time in seconds. In the circuit L = 20.0 mH, R = 22.7 kΩ and C = 0.42 μF. a) Determine the impedance and phase difference of the circuit. b) What is the effective power of the circuit? c) What are the effective currents and effective voltages for each component?

In an RLC series circuit, the voltage amplitude and frequency of the source are 100 V...

In an RLC series circuit, the voltage amplitude and frequency of the source are 100 V and 500 Hz, respectively, and R = 510 Ω, L = 0.23 H, and C = 2.7 µF. (a) What is the impedance of the circuit (in Ω)?___________Ω (b)What is the amplitude of the current from the source (in A)?_________A (c)If the emf of the source is given by v(t) = (100 V)sin(1,000πt), how does the current vary with time? (Use the following as...

An LRC circuit is connected to a 10.0-kHz, 745-V (rms) source, L = 29.0 mH ,...

An LRC circuit is connected to a 10.0-kHz, 745-V (rms) source, L = 29.0 mH , R = 8.60 kΩ , and C = 6550 pF Part A Determine Impedance Part B Determine phase angle Part C Determine rms current

using the laplace transforms, find the charge and the current in a series LRC circuit where...

using the laplace transforms, find the charge and the current in a series LRC circuit where L = 1/2 h R = 10 ohms C = 1/30 f E(t) = 300V q(0) = 0 C i(0) = 0 A

In an LRC series circuit, the components have the following Values: L=0.4 H, C=600 μF, R=200...

In an LRC series circuit, the components have the following Values: L=0.4 H, C=600 μF, R=200 Ω, V=30 V and frequency 1.5 kHz. Calculate the impedance of the circuit Calculate the maximum voltage across the resistor, the inductor and the capacitor

[Series circuit analogue: RLC circuit with nonzero resistance R and nonzero voltage E(t) as forcing function...

[Series circuit analogue: RLC circuit with nonzero resistance R and nonzero voltage E(t) as forcing function is analogous to a forced damped spring/mass system.] Consider the RLC circuit with inductance L = 8 henrys, resistance R = 16 ohms, capacitance C = 0.025 farads, and voltage E(t) = 17 cos 2t volts. (a) Find the current in the circuit for t > 0, given that at time t = 0 the capacitor is uncharged and there is no current flowing....

If the instantaneous value of a voltage in an AC circuit of the communication system (at...

If the instantaneous value of a voltage in an AC circuit of the communication system (at any time t seconds) is given by V= 142sin(8πt-0.125π) volts, determine: a. The amplitude, b. Periodic time (in ms) c. Frequency d. Phase angle in degrees e. Voltage at t=0 f. Voltage at t=10ms g.Time when voltage reaches 100volts h. Time when voltage is maximum i. Sketch one cycle of the waveform j. Given that the voltage waveform can also be represented as V=Rsin(ωt+θ),...

Find the steady-state current i(t) in an RLC-ciruit with R=4 (ohms), L=0.5 H( henry), C=10-1F (farad),...

Find the steady-state current i(t) in an RLC-ciruit with R=4 (ohms), L=0.5 H( henry), C=10-1F (farad), which is connected to a source of EMF E(t)= 500 sin 2tV.