3. Design a bandpass FIR filter using Kaiser's formula for filter order, using Hamming window with...
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...
Design a linear-phase, bandpass FIR filter using the window-based approach to meet the following specifications: ws,L = 0.3T,ap.L = 0.45T,Wp u = 0.65T, "Au-0.8T, mini- mum stopband at (i) Is there a unique window to meet the desired specifications? If not, choose the window with minimum transition width (ii) Plot the magnitude and phase response of the designed filter using MATLAB. (iii Using the MATLAB command firpm, design the same linear-phase bandpass FIR filter via the Parks-McClellan algorithm. Plot the...
Design a 5-tap FIR bandpass filter with a lower cutoff frequency of1,600 Hz, an upper cutoff frequency of 1,800 Hz, and a sampling rateof 8,000 Hz using a. rectangular window functionb. Hamming window function.Determine the transfer function and difference equation of the designedFIR system, and compute and plot the magnitude frequency responsefor Ω= 0, π/4, π/2, 3π/4, and π radians.PLEASE SHOW STEPS CLEARLY
1. Design a 10th-order lowpass FIR filter using the window method (fir1) to cut frequencies above 30Hz in an application where the sampling frequency is 125 Hz. 2. Plot the filter coefficients that define the filter (stem). 3. Plot the frequency response of the FIR filter designed (freqz) 4. Design a 100th-order lowpass FIR filter using the window method (fir1) to cut frequencies above 30Hz in an application where the sampling frequency is 125 Hz. Plot the filter coefficients that...
matlab code as well please. 7. (100) Design a bandpass FIR filter with the following Spec: (a) Lower cut off frequency: 1250Hz, (b) lower transition width: 1500Hz, (c) upper cutoff frequency: 2850 Hz, (d) upper transition width: 1300 Hz, (e) stop band attenuation: 60dB, (f) passband ripple 0.02 dB, and (g) sampling frequency: 8000Hz. Your answer needs to include (i) normalized frequencies, (ii) Window type, (iii) order of the filter and their numerical values computed by matlab command firwd(), and...
1 Design a 4th order causal FIR bandpass filter with cutoff frequencies at 9 kHz and 18kHz and sampling frequency of 54 kHz. Use a Blackman window. Give precise numerical values for the filter coefficients. The Blackman window has coefficients as shown below (you need choose one window among the three listed below so that a 4 order linear phase filter is designed. (Circle the one you choose). (35pts) Blackman window 1 O.2008 0.8492 0.8492 0.2008 Blackman window 2 0.1300...
Consider an FIR lowpass filter design with the following specifications: Passband Stopband Passband ripple Stopband attenuation Sampling rate Determine the following: a. window method b. length of the FIR filter c. cutoff frequency for the design equation We were unable to transcribe this imageWe were unable to transcribe this image= 1200 4000H = 0.1dB We were unable to transcribe this imageWe were unable to transcribe this image
The MATLAB program below designs a lowpass filter for a passband edge frequency of 250Hz and a stopband edge of 350Hz. The sampling frequency is 2kHz. A Hamming window is used. (a) The program is on Webcampus. Run it and copy and paste the wvtool plots into Word. % FIR Filter Design (using wvtool) % Lowpass Design clear fpass 250; fstop 350; fs 2000; wp 2*pi* fpass/ fs; ws 2* pi fstop / fs; M=ceil(6.6 * pi / (ws-wp)) +...
please need correct answer. I will upvote. Design a second-order digital bandpass Butterworth filter with a lower cutoff frequency of 1.9 kHz, an upper cutoff frequency 2.1 kHz, and a passband ripple of 3dB at a sampling frequency of 8,000 Hz. a. Determine the transfer function and difference equation. b. Use MATLAB to plot the magnitude and phase frequency respon
using Matlab: 1) Design an FIR notch filter using zero placement to remove power-line noise at 60 Hz (use file ecg_60hz_200, fs = 200 Hz). 2) Design a LP Butterworth filter with cut-off frequency of 40 Hz to remove high-frequency noise (use file ecg_hfn.dat, fs = 1000 Hz). 3) Design an Elliptic HP filter with passband ripple of 0.01 dB and stopband attenuation of 50 dB and cut-off frequency of 0.5 Hz to remove low-frequency noise (use file ecg_lfn.dat, fs...