I am working on a seiries RCL circuit. give values are R1 =45ohms C1= 450nF L1...

1) In an LRC circuit, why does the sum of the voltages around the circuit not...

1) In an LRC circuit, why does the sum of the voltages around the circuit not equal the applied voltage as Kirchhoff’s rule requires? 2) Using L = 20 mH, C = 50 ?F and R = 15 ohms, calculate the resonant frequency of the series LRC circuit. Show your work in the space below. 3) Using the values from pre-lab question 2 and an applied voltage of 3.0 volts across the circuit, plot (on a separate sheet) the voltage...

A series RLC circuit is driven by a voltage source which provides a time varying emf...

A series RLC circuit is driven by a voltage source which provides a time varying emf of ϵ = 100cos(8000t)V and consists of an resistor, capacitor and inductor with values of R = 100 Ohms, L = 1.00 mH, C = 1.00 µF a) What is the phase constant of the current? Enter your answer in radians. b) When the potential across the resistor is 0 V, what is the potential across the inductor? You might find a phasor diagram...

Now let's apply Z=R2+[ωL−(1/ωC)]2−−−−−−−−−−−−−−−−−√ and tanϕ=X/R to a specific R-L-C circuit. The circuit layout is shown...

Now let's apply Z=R2+[ωL−(1/ωC)]2−−−−−−−−−−−−−−−−−√ and tanϕ=X/R to a specific R-L-C circuit. The circuit layout is shown in (Figure 1). Suppose that its components have values R=300Ω, L=60mH, C=0.50μF, V=50V, and ω=10,000rad/s. Find the reactances XL, XC, and X, the impedance Z, the current amplitude I, the phase angle ϕ, and the voltage amplitude across each circuit element. In a series circuit, suppose R=130Ω, L=350mH, C=0.70μF, V=120V, and ω=4050rad/s. Find the reactance XL. Express your answer in ohms to two significant...

An ac circuit consists of a 1.00 x 102 Ω resistor, a 1.00 x 10-1 H...

An ac circuit consists of a 1.00 x 102 Ω resistor, a 1.00 x 10-1 H inductor, and a 1.00 x 10-5 F capacitor connected in series with each other and with a generator that supplies a voltage ΔVT = 140 V sin (500t + φ ). 1. Find the following quantities: (a) the impedance, (b) the rms current, (c) the rms voltage drops across the: resistor, inductor and capacitor (d) the average power loss, (e) the phase angle, (f)...