w R Vinn Vou V. R W (a) (b) An alternating square wave signal f(t) has...
Given Answers Problem 18.2 For the following circuit, when input V(t)Acos(5000), we measure steady-state output ).3416cos(5000t +0), and when V (t)- Acos(8000r) we measure steady-state output r_(t)-1.1714cos(8000t +0,). If R-100Ω, find A, 9,4, and L. Vout Vin Fig 26.2: Passive RL circuit. A-1.5 V, L-10 mH,0,--0.46 rad, θ2-_0.67 rad Problem 18.2 Problem 18.2 For the following circuit, when input V(t)Acos(5000), we measure steady-state output ).3416cos(5000t +0), and when V (t)- Acos(8000r) we measure steady-state output r_(t)-1.1714cos(8000t +0,). If R-100Ω, find...
R t = i(t) C 2011P E e p gP a P9.09 10ed The voltage applied to this circuit at t 0 (when the switch closes) is v (t) = 75 cos (4,000t - 60°) Volts Also given that R = 400 2 (0hm) and L=75 mH (milli Henry) The initial inductor current is zero for t< 0 The textbook gives you the total response equation as: )_ ?(0-¢)so R2+(w L) Cos(wt+¢-e) -V V m i(t)=itransient(t)+isteady.state(t)=R2 +(wL m - ㅎCOS...
1. Use Eq. 1 to derive an expression for the expected output waveform from an ideal differentiator circuit having input waveform Vin=lsin[(21)1000t] V. Let RF1.5 k12 and C=10 nF. 2. Use Eq. 3 to find the peak-peak output amplitude of the ideal differentiator of question 1 for a 2 Vpp sine wave input at 1 kHz and 2 kHz. Put the results in the Calculated Output column of Table 1 in Appendix A. 3. Use the indefinite integral version of...
Consider the circuit of Figure 6.19. The AC supply has a peak voltage of 10 V and a frequency of 1 kHz. The resistor has a value of 1 k2, and the capacitor has a capacitance of 0.1 F. a. find the Thevenin equivalent circuit b. If we varied the frequency of the source, at what frequency would the impedence be: i. Maximum ii. Minimum iii. What are the impedences for cases 9(b)i and 9(b)ii ? c. Now we connect...
In the circuit below, the input voltage is Vin-Vinegakcos(wt), R-20 ΚΩandC15nFw l. in al Show that the output voltage is VotVcos (wt-), where V-V n peak/V1 + (RC) b) Show that this result justifies calling this circuit a high-pass filter+ c) Find an expression for the phase constant δ in terms of R,C and d) At what frequency is Vi (1/V2) Vin peak? That particular frequency is known as the 3dB frequency, or f3dB, of the circuit In the circuit...
For the circuit shown below: Vs W RG R W Vs=32 sin( 20 t) V, R=30 0, L= 1.5 H, if the firing angle is 30 Find the average output voltage in V.
The alternating signal with an amplitude of 0.9 V, a frequency of 1 KHz, and a phase of -22.5° is o.TV dc b.as. Try connecting this signal to a load resistance of 50 Q to test the waveform 1.Express circuit as CAD drawing 2.Show output graph through Transient analysis in PSPICE 3.Calculate the instantaneous value at 0.1 second and compare it with the result of 2 4.When connecting the signal to the A and B terminals of the voltage distribution...
Problem 3: Find the voltage v,f) across the capacitor as a function of time for i> 0 for the circuit below. Assume steady-state conditions exist at r D t-0 10Ω ЗА
Need help solving part d. I 4. An alternating voltage source (15 V rms) drives the circuit shown here at f=1.00 kHz, where L = 175 mH and R= 1.80 k22, a. What is the total impedance of the circuit? R A. 16702 B. 1890 22 - 000000 C. 2110 22 D. 2320 2 E. 2560 22 w b. What is the peak value of the current in the circuit? A. 10.1 mA B. 15.6 mA C. 22.3 mA D....
Ov 4) In the above circuit, the alternating voltage source has frequency , am- plitude Vo, and R-Ve. At steady state, calculate how much the phase of the charge on the capacitor lags the voltage when w is equal to 1/2, 2/2, 3/2, and 4/2 the resonant frequency o Vte Ov 4) In the above circuit, the alternating voltage source has frequency , am- plitude Vo, and R-Ve. At steady state, calculate how much the phase of the charge on...