3. Calculate the transfer function Vo(o)/Vi(c) and then determine the type of filter (i.e. low pass,...
2. Consider the given C-R filter. a. (4) Determine the transfer function H(jo) in terms of R, C and o. b. (3) Express the transfer function in polar form i.e. find the magnitude and phase expressions. c. (3) Calculate the half-power or cut-off frequency of this filter in rad/s for R = 250 2 and C= 15 nF. d. (4) Plot the magnitude response H(jo) using linear scale. Label both axes. Label maxima, minima, and cut-off frequency points numerically on...
What type of filter is the circuit? a) Low Pass b) High pass c) Band stop d) Band pass What type of filter is the circuit? a) Low pass b) high pass c) band stop d) band pass I + What type of filter is the circuit? a) Band Pass b) Low pass c) Band stop d) High pass
Determine the transfer function for a 2nd order Chebyshev low pass filter with 3dB frequency of 100krad/sec, a maximum gain of OdB, and a passband ripple of 1dB. (40 points) (a) (b) A bandpass filter is made by cascading the filter described in part (a) with a 2nd order Chebyshev high pass filter with 3dB frequency of 1krad/sec, a maximum gain of OdB and passband ripple of 2dB. Determine the midband gain of the filter. (30 points) A Chebyshev bandpass...
C V. Figure 2 A band-pass filter circuit This is the transfer function of a band-pass filter having R = R2 //R Center frequency, a[ 1/R' R C12 radians Bandwidth B2(R, C) radians Maximum Gain Ag- R/2R Band-Pass Filter Design Design a band-pass filter to obtain f-160 Hz, B-16 Hz and o- 10. Supply voltages of +20 and -20 Volts are available. Laboratory Measurements and Results . By applying sinusoidal voltage at the input and by varying its frequency, obtain...
1. Derive the transfer function for the low pass filter shown in Figure 1. The general form is: H(s) w? W. s2 + +w? 2. Determine the component values by equating the derived transfer function to the general transfer function to meet the following specifications: a) fc = 2 kHz, and Q = 0.7071 for a Butterworth response. HH Vi R R C2 HHI Figure 1. Low-Pass Filter
just do 4 , 3 is solved
3. Use a Bilinear Transform to design a Butterworth low-pass filter which satisfies the filter specifications: Pass band: -1Ss0 for 0sf s0.2 Stop band: (e/40 for 0.35sf s0.s Transition Band: 0.2<f<0.35 Sampling Frequency: 10 kHz a. (3) Determine the stop-band and pass-band frequencies, Fstop and Fpas, in kHz. b. (3) Calculate the fater order, n, which is necessary to obtain the desired filter specifications. (3) Calculate the corner frequency, Fe, if you want...
A single stage band pass filter was created. The low pass filtering stage consists of a 5kohm resistor and a 0.3nF capacitor. The high pass filtering stage consists of a 10nF capacitor and a 1,6kOhm resistor. a. Determine an equation and calculate the frequency at which the output voltage is 10% that of the input voltage. b. Determine an equation and calculate the frequency at which the power transfer is -10dB.
a) The transfer function of an ideal low-pass filter is and its impulse response is where oc is the cut-off frequency i) Is hLP[n] a finite impulse response (FIR) filter or an infinite impulse response filter (IIR)? Explain your answer ii Is hLP[n] a causal or a non-causal filter? Explain your answer iii) If ae-0. IT, plot the magnitude responses for the following impulse responses b) i) Let the five impulse response samples of a causal FIR filter be given...
What kind of filter has poles in the imaginary left half plane? (Low pass, high pass, band pass, or band reject). A brief explanation of the transfer function(s) would be great, I am having a hard time understanding the concept behind this. Thank you.
Question # 2 For the filter shown: a) Write an expression for the filter transfer function Vo(oVs() b) Determine the filter type. c) Based on the filter type, Calculate the filter cut off frequency or frequencies. 1.0 Vs(o) (* 1 10 Vo(t)