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Finally, design a bandpass filter using this type of filter, with anfo 1500 Hz, and a...
BPF Filter Bandpass Filter The following circuit acts as a C This filter has a center...
BPF Filter Bandpass Filter The following circuit acts as a C This filter has a center (resonance) frequency at Hz. 27-VLC and a 3-dB bandwidth of BW = Hz. 2RC 3l f, and a passband for which the signal is This means that the filter has 0 dB gain at attenuated less than 3 dB centered approximately at f, from f,-BW2 to f.+BW/2 (this passband is not exactly centered at f, but its total width is BW) 3l8 Input Signal...
Design an active unity-gain bandpass filter with center frequency 750 Hz and bandwidtg 250 Hz and...
Design an active unity-gain bandpass filter with
center frequency 750 Hz and bandwidtg 250 Hz and with 0.1 μF
capacitor, R1=6.4kΩ, R2=377Ω, and R3=12.7kΩ.
a)Discuss the circuit response with support of a Bode
magnitude plot.
b) Assume next that a load R_L is connected to the output of the
network at the terminal Vo(s). How does the frequency response of
the loaded configuration change?
c) Consider a broadband bandpass op amp filter with center
frequency 2.4 kHz and bandwidth 800...
Design a bandpass filter, using a cascade connection, to give a center frequency of 600 Hz,...
Design a bandpass filter, using a cascade connection, to give a center frequency of 600 Hz, a bandwidth of 2 kHz, and a passband gain of 4. Use 250 nF capacitors. Part A Specify fal Express your answer to three significant figures and include the appropriate units. Part B Specify f2. Express your answer to three significant figures and include the appropriate units. Part C Specify RL Express your answer to three significant figures and include the appropriate units. Part...
1. Design a parallel RLC bandpass filter, derive the transfer function H(s). Compute the center frequency, Wo. Calculate the cutoff frequencies Wej and Wc2, the bandwidth ß, and quality factor, Q. Co...
1. Design a parallel RLC bandpass filter, derive the transfer function H(s). Compute the center frequency, Wo. Calculate the cutoff frequencies Wej and Wc2, the bandwidth ß, and quality factor, Q. Compute values for R and L to yield a bandpass filter with a center frequency of 5kHz and a bandwidth of 200Hz, using a 10nF capacitor. (25 points)
1. Design a parallel RLC bandpass filter, derive the transfer function H(s). Compute the center frequency, Wo. Calculate the cutoff frequencies...
7.29. Design a 41-tap bandpass FIR filter with lower and upper cutoff frequencies of 2,500 Hz...
7.29. Design a 41-tap bandpass FIR filter with lower and upper cutoff frequencies of 2,500 Hz and 3,000 Hz, respectively, using the following window functions. Assume a sampling frequency of 8,000 Hz. a. Hanning window function b. Blackman window function. List the FIR filter coefficients and plot the frequency responses for each design. 7.30 Design a 41-tap band reject FIR filter with cutoff frequencies of 2,500 Hz and 3,000 Hz, respectively, using the Hamming window function. Assume a sampling frequency...
13.60 A second-order band-pass filter is required with a center frequency of fo 54 kHz and a pass...
13.60 A second-order band-pass filter is required with a center frequency of fo 54 kHz and a passband gain of +50 dB. If the filter is implemented using the circuit of Fig. 13.15 with C1-C2, choose appropriate values for Ri and R2. What is the resulting value of for the filter? What is its bandwidth? Ci Figure 13.15 Second-order active bandpass filter of the Sallen-Key type. R2 C2 Ri UIN OUT
13.60 A second-order band-pass filter is required with a...
Design an active band-pass filter such that the center frequency is Fo-2.5 kHz, bandwidth is BW...
Design an active band-pass filter such that the center frequency is Fo-2.5 kHz, bandwidth is BW 400 Hz and gain is K-3 for Figure 10.5. Find the values for the capacitors, and resistors. Compute the theoretical values of Vout and |Av Vout / V l and record the results in Table 10.5-A. VEE -15V C1 R3 C2 R1 R2 Vout +VCC +15V Figure 10.5
Problem 4. (6 marks) You are required to design a third-order Butterworth bandpass filter using ideal...
Problem 4. (6 marks) You are required to design a third-order Butterworth bandpass filter using ideal operational (6) Passband gain of 12 dB. (i) Lower cutoff frequency, f 6000 Hz. (ii) Upper cutoff frequency, u 12000 Hz. You are constrained to using 1 k? resistors in the lowpass filter and 10 nF capacitors in the highpass filter. Sketch the overall schematic design of your filter with all component values clearly labelled. You must show all of your work in obtaining...
3. Design a bandpass FIR filter using Kaiser's formula for filter order, using Hamming window with...
3. Design a bandpass FIR filter using Kaiser's formula for filter order, using Hamming window with the following specifications: the lower passband and stopband edge frequencies are fpi- 700 Hz, fs1 - 300 Hz, the upper passband and stopband edge frequencies fp2 - 2 kHz fs2 - 2400 Hz, the sampling frequency fs-10 kHz, and 6p-0.03, ando0.004.
Problem 4 Use a 5 nF capacitor to design a series RLC bandpass filter. The center...
Problem 4 Use a 5 nF capacitor to design a series RLC bandpass filter. The center frequency the filter is 8 kHz, and the quality factor is 1.5. Part A Specify the value of L. View Available Hint(s) EVO AQH vec ? L = 0.079 ml Submit Previous Answers * Incorrect; Try Again; 8 attempts remaining Part B Specify the value of R. 10 AEDIf vec ? R = k12 Submit Request Answer Problem 4 Use a 5 nF capacitor...
BPF Filter Bandpass Filter The following circuit acts as a C This filter has a center (resonance) frequency at Hz. 27-VLC and a 3-dB bandwidth of BW = Hz. 2RC 3l f, and a passband for which the signal is This means that the filter has 0 dB gain at attenuated less than 3 dB centered approximately at f, from f,-BW2 to f.+BW/2 (this passband is not exactly centered at f, but its total width is BW) 3l8 Input Signal...
Design an active unity-gain bandpass filter with
center frequency 750 Hz and bandwidtg 250 Hz and with 0.1 μF
capacitor, R1=6.4kΩ, R2=377Ω, and R3=12.7kΩ.
a)Discuss the circuit response with support of a Bode
magnitude plot.
b) Assume next that a load R_L is connected to the output of the
network at the terminal Vo(s). How does the frequency response of
the loaded configuration change?
c) Consider a broadband bandpass op amp filter with center
frequency 2.4 kHz and bandwidth 800...
Design a bandpass filter, using a cascade connection, to give a center frequency of 600 Hz, a bandwidth of 2 kHz, and a passband gain of 4. Use 250 nF capacitors. Part A Specify fal Express your answer to three significant figures and include the appropriate units. Part B Specify f2. Express your answer to three significant figures and include the appropriate units. Part C Specify RL Express your answer to three significant figures and include the appropriate units. Part...
1. Design a parallel RLC bandpass filter, derive the transfer function H(s). Compute the center frequency, Wo. Calculate the cutoff frequencies Wej and Wc2, the bandwidth ß, and quality factor, Q. Compute values for R and L to yield a bandpass filter with a center frequency of 5kHz and a bandwidth of 200Hz, using a 10nF capacitor. (25 points)
1. Design a parallel RLC bandpass filter, derive the transfer function H(s). Compute the center frequency, Wo. Calculate the cutoff frequencies...
13.60 A second-order band-pass filter is required with a center frequency of fo 54 kHz and a passband gain of +50 dB. If the filter is implemented using the circuit of Fig. 13.15 with C1-C2, choose appropriate values for Ri and R2. What is the resulting value of for the filter? What is its bandwidth? Ci Figure 13.15 Second-order active bandpass filter of the Sallen-Key type. R2 C2 Ri UIN OUT
13.60 A second-order band-pass filter is required with a...
Design an active band-pass filter such that the center frequency is Fo-2.5 kHz, bandwidth is BW 400 Hz and gain is K-3 for Figure 10.5. Find the values for the capacitors, and resistors. Compute the theoretical values of Vout and |Av Vout / V l and record the results in Table 10.5-A. VEE -15V C1 R3 C2 R1 R2 Vout +VCC +15V Figure 10.5
Problem 4. (6 marks) You are required to design a third-order Butterworth bandpass filter using ideal operational (6) Passband gain of 12 dB. (i) Lower cutoff frequency, f 6000 Hz. (ii) Upper cutoff frequency, u 12000 Hz. You are constrained to using 1 k? resistors in the lowpass filter and 10 nF capacitors in the highpass filter. Sketch the overall schematic design of your filter with all component values clearly labelled. You must show all of your work in obtaining...
3. Design a bandpass FIR filter using Kaiser's formula for filter order, using Hamming window with the following specifications: the lower passband and stopband edge frequencies are fpi- 700 Hz, fs1 - 300 Hz, the upper passband and stopband edge frequencies fp2 - 2 kHz fs2 - 2400 Hz, the sampling frequency fs-10 kHz, and 6p-0.03, ando0.004.
Problem 4 Use a 5 nF capacitor to design a series RLC bandpass filter. The center frequency the filter is 8 kHz, and the quality factor is 1.5. Part A Specify the value of L. View Available Hint(s) EVO AQH vec ? L = 0.079 ml Submit Previous Answers * Incorrect; Try Again; 8 attempts remaining Part B Specify the value of R. 10 AEDIf vec ? R = k12 Submit Request Answer Problem 4 Use a 5 nF capacitor...
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