Here is my Matlab/Octave program
clc; close all; %BPF of pass 400-600Hz fs1=300; fp1=400; fp2=600; fs2=700; samp=1500; ap=1; %passband ripple as=60; %stopband attenuation %Normalizing the frequency wp=[fp1 fp2]/(samp); ws=[fs1 fs2]/(samp); [N,wn]=cheb1ord_test(wp,ws,ap,as); %Generates order and cutoff parameters [b,a]=cheby1(N,ap,wn); %Generates poles and zeros for the given order and cutoff printf("b coeffs = %f\n",b); printf("a coeffs = %f\n",a); [H,W]=freqz(b,a,256); plot(W/(2*pi),20*log10(abs(H))) %Transfer function works correctly, so coefficients are correct %100 samples of 500hz n = 1:100; x=10*cos(2*pi*n*500*(1/samp)); printf("Order %d\n",N); %Depends on required ripple attenuation figure; subplot (2,1,1); plot(x); y=filter(b,a,x); %**Apparently i suspect this does not work** subplot (2,1,2); plot(y);
When i see the magnitude/frequency response, the graph is perfect and indicates 400 and 600 to be my filter cutoffs.
But however when i apply an input signal of 500Hz, i must expect to see the signal pass through the filter unharmed (as observed when i used Butterworth function), but the output is distorted and almost contains no signal
So i infer that my mistake is using the filter function to combine the chebyshev coefficients with the input signal.
If this is the problem, then how do i apply chebyshev coefficients to an input digital signal ?