1) SuperpositionV2(V1R1W1kC11E-6In the above circuit, V1 is a DC source and V2 is a sinusoidal source, with voltagesV1 = 2V (assume the capacitor is at DC steady state for VI, ie. not a step functioninput)V2 = 2sin(@t) Va)For c=1000 [rad/s], use superposition to determine the time domain expression forthe voltage across the capacitor, Vc.b)Assuming the minimum capacitor voltage should never be less than IV, what is theoperating frequency range of V2?

Given Data:An RC series circuit with,DC voltage AC voltage The passive components To Find:a. The…

Answered: 1) Superposition V1 R1 www 1k C1 1E-6…

Introductory Circuit Analysis (13th Edition)

13th Edition

ISBN:9780133923605

Author:Robert L. Boylestad

Publisher:Robert L. Boylestad

Chapter1: Introduction

Section: Chapter Questions

Problem 1P: Visit your local library (at school or home) and describe the extent to which it provides literature...

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Charging Capacitor: For a charging capacitor the Kirchoff's Loop Rule gives R E – IR C ww C In this case the current is entering the positive plate so I = dQ/dt = CdAVc/dt and we get dVc E – RC - Vc = 0 dt The solution to the differential equation is V.(t) = E (1 – e-t/(RC)) (charging capacitor) Notice that V.(0) = 0 and V.(0) = E as we expect for a charging capacitor. 5. You can easily find the time constant if you are given a graph of voltage across a charging capacitor as a function of time. Whent = RC, the voltage across the capacitor is V.(t = RC) = E(1 – e-1) × 0.63 E. Therefore the time constant is just how long it takes for AV(t) to reach 63% of the EMF. The graph shows the voltage across a charging capacitor as a function of time. The resistance of the circuit is 7.5 kN. а. Determine the capacitance of the capacitor. 10 8 60 40 time (ms) 20 80 100 b. What is the current at t = 10 ms? Hint: the easiest way to do this is to use the loop rule. (volts) 4.
R t= 0 i(t) Find the steady state component value of i(t) at t = 1msec for the values Vs = Vmcos (wt + p) Vm = 10V w = 1000 rad/s P = 60° R = 100 L = 10mH Lütfen birini seçin: a.0.3265 b.0.6254 C.0.7856 d.0.3254 e.0.6797 f.0.4125 g.0.9785 h.0.1245
You are asked to build a sinusoidal waveform generator for a frequency of 10,000 Hz. You have not designed this before. You start a brainstorming session with your team by examining a series RLC circuit. One of your team members points out that the step response of the series RLC circuit with complex roots would have an exponentially decaying sinusoidal response. The team member argues that if we eliminate exponent from the time response by making appropriate changes in the circuit or component values, we could get a sinusoidal signal at any desired frequency. After some discussion you decide to follow this approach. 1. Design a series RLC circuit with a resonant frequency of 10 kHz. Use C = 1.0 nF and compute the other component values for your design. 2. Implement and test the circuit. Document all your measurements and observations. Questions: 1. Were you able to design, build, and test the circuit to meet all the requirements of this experiment? Please explain any discrepancies in…
1
need help with d e and f
A series circuit containing R, L and C is excited by a step voltage input. The voltage across the capacitance exhibits oscillations. Damping coefficients (ratio) of circuit is given by R a) 8=> 2√LC c) 8= R 2√CIL b) 8= d) 8= R LC R 2√LIC
The voltage across a capacitor in a series RC circuit is given by the equation Vc = 250 (1-e25t), how long after the switch is closed will the capacitor emf be 100 volts? Use the editor to format your answer
Exercise 3: Plotting two signals together (Matlab function: hold) Plot the following sinusoidal and exponential signals together between 0 to 8ms with step size le-5. x(t)=, a=(S1+S2)/1e4 fo2 = (270+K2) Hz, K2=(S1+S2)/1e6 02 Hint: Some helpful commands Definition of x (t) %% X=exp (-a*T) ; Definition of y(t) %% Y=cos (2*pi*fo.*T-pi/4) ; plot (T, X, 'k', 'linewidth', 2); hold; plot (T, Y, 'r-. ', 'linewidth', 2); hold; 1 0.8 0.6 0.4 0.2 受。 -0.2 -0.4 -0.6 -0.8 -1 0 x(t)=exp(-at),y(t)=cos(wt-pi/4), a=722.22 fo=277.22 1 2 3 4 Time (seconds) 5 6 7 8 X10-3
Please answer in typing format solution please only typing format solution please Please I will like it please reply
An 50 resistor, a 5 mH inductor, and a 1.25 μF capacitor are connected in series. The series-connected elements are energized by a sinusoidal voltage source whose voltage is 600 cos(8000t+ 20°)V. Part A Determine the impedances of the elements in the frequency-domain equivalent circuit. Express your answers in ohms to three significant figures separated by commas. Enter your answers in rectangular form. ZL, ZC, ZR= Submit Part B ΠΫΠΙ ΑΣΦ Ig= Request Answer ΑΣΦ | 11 Ivec Reference the current in the direction of the voltage rise across the source, and find the phasor current. Express answer in amperes to three significant figures. Enter your answer using angle notation. Express argument in degrees. vec ? ? A Ω

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