1. For a particular RLC series circuit, the capacitive reactance is 4.65 Ω, the inductive reactance...

16. In an RLC circuit, a resistor R x 8 Ohm, a capacitor of 330 micro...

16. In an RLC circuit, a resistor R x 8 Ohm, a capacitor of 330 micro Faraday, and an inductance of 50 mH are connected in series. The circuit is connected to an alternating source that delivers a voltage equal to: V-250- without (314 t) (volts) Identify and calculate: a) The maximum voltage of the source. b) The frequency of the source. c) The RMS voltage of the source. d) Capacitive reactance. e) Inductive reactance. f) The impedance of the...

The RLC series circuit illustrated in the simulation has R = 1.49 Ω, L = 1.25...

The RLC series circuit illustrated in the simulation has R = 1.49 Ω, L = 1.25 H, and C = 198 µF. The applied AC voltage has a frequency of f = 60 Hz and a voltage of Δv = 120 V. 1-Find the inductive reactance, capacitive reactance, and impedance. XL = ........ Ω XC = ........ Ω Z = ......... Ω 2-Find the phase difference between current and voltage............. ° 3-Find the voltages ΔvR, ΔvL, and ΔvC. ΔvR =...

a) At what frequency will the Inductive Reactance of 44. mH be equal to the capacitive...

a) At what frequency will the Inductive Reactance of 44. mH be equal to the capacitive reactance of a 27.0 pF capacitor? b) A 120.0 mH inductor is in series with a 20.0 Ω resistor in a 120.0V, 60.0 Hz circuit. What is the impedance of the circuit?

The phase angle of an LRC series circuit with a capacitive reactance of 200 Ω, a...

The phase angle of an LRC series circuit with a capacitive reactance of 200 Ω, a resistor of 100 Ω and a certain inductor at 1000 Hz is 40.0°. What is the value of the inductance in this circuit?

Consider a driven RLC series AC circuit. At frequency f1 the capacitive reactance is twice the...

Consider a driven RLC series AC circuit. At frequency f1 the capacitive reactance is twice the inductive reactance. Determine frequency f2 as a function of f1 so that the inductive reactance is twice the capacitive reactance. Select one: a. f2=f1/sqrt(2) b. f2= sqrt(2)f1 c. f2= 2f1 d. f2=f1/2

Now Tiva and Graciela try a problem from the book. The RLC series circuit illustrated in...

Now Tiva and Graciela try a problem from the book. The RLC series circuit illustrated in the simulation has R = 1.2 Ω, L = 1.02 H, and C = 183 µF. The applied AC voltage has a frequency of f = 60 Hz and a voltage of Δv = 120 V. Find the inductive reactance, capacitive reactance, and impedance. XL =____ Ω XC =____ Ω Z =____ Ω Find the phase difference between current and voltage. ° Find the...

Consider a series RLC circuit where R = 651 Ω and C = 6.25 μF. However,...

Consider a series RLC circuit where R = 651 Ω and C = 6.25 μF. However, the inductance L of the inductor is unknown. To find its value, you decide to perform some simple measurements. You apply an ac voltage that peaks at 72.0 V and observe, using an oscilloscope, that the resonance angular frequency occurs at 39700 s–1. What is the inductance of the inductor in millihenrys?

In an LRC series circuit, the inductance is 244 mH, the resistance is 29 Ω, and...

In an LRC series circuit, the inductance is 244 mH, the resistance is 29 Ω, and the capacitance is 354 μF. If the AC voltage applied across the circuit is given by V(t) = (12 V)sin(11πt) calculate the voltage across each element at a time of t = 0.04 s. VR = V VC = V VL = V

5)A series circuit consisted of R= 4.7?, L= 2.0 mH , 2200 µF is connected to...

5)A series circuit consisted of R= 4.7?, L= 2.0 mH , 2200 µF is connected to an alternative voltage with maximum voltage of Vm = 12.0 V and frequency of 60.0 Hz. Find the following- show the formula- substitute- calculate – put final result in a box with its unit, a ) Inductive Reactance b)Capacitive Reactance c) Impedance d)maximum current in the circuit e) Voltage across the resister f)Voltage across the inductor. g)Voltage across the capacitor h) RMS voltage across...

Consider a series RLC circuit with R = 24 Ω, L = 6.0 mH, and C...

Consider a series RLC circuit with R = 24 Ω, L = 6.0 mH, and C = 32 μF. The circuit is connected to a 10-V (rms), 600-Hz AC source. (a) Is the sum of the voltage drops across R, L, and C equal to 10 V (rms)? (b) Which is greatest, the power delivered to the resistor, to the capacitor, or to the inductor? (c) Find the average power delivered to the circuit.  W