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When I recreate a signal it seems to look great. But when I try and increase it's frequency (which is done in a for loop and the variable new_freq=2) it starts to drift.

See Image below (The top image is 1hz and the bottom image is 2hz. I circled the image with the problem). I also noticed when I increase the sample frequency the problem gets even more noticeable. Notice the top one is at 8000 as the sample frequency and the bottom one is at sample frequency of 44100.

The whole for loop is base on rebuilding a signal using the equation Amplitude*Cos(freq*time+phase) I did an fft/ifft to get all the frequencies/amplitudes/phases then just change the frequency to what I want it to be.

I've posted the for loop below any ideas why the variables aa_sig_rebuilt_norm_bin and aa_sig_combined_norm_bin are drifting so much?
Please note I'm using much more complex signals than just sine waves (if I were just using sine waves I would use the sinwave equation to increase the frequency. I used a sinewave as an example)

new_freq=[2]; %increase frequency
fn_array=[];
array1=[xfreq_orig,yamp_orig,yamp_inv,phase_orig,mod(phase_in_deg,360),phase_in_rad,phase_adjindeg,phase_adjinrad]; %have degs only go up to 360

t_rebuilt=linspace(0,2*pi,fs);

for zz=1:1:length(new_freq); %

    zz
    %needs to be in for loop to reset variables for next new_freq
    aa_sig_rebuilt_norm=zeros(1,length(t_rebuilt));
    aa_sig_rebuilt_norm_bin=zeros(1,length(t_rebuilt));
    aa_sig_combined_norm=zeros(1,length(t_rebuilt));
    aa_sig_combined_norm_bin=zeros(1,length(t_rebuilt));
    sig_norm=zeros(1,length(t_rebuilt));
    sig_norm_bin=zeros(1,length(t_rebuilt));
    for kk=1:1:length(xfreq_orig);
        aa_sig_rebuilt_norm = array1(kk, 2)*cos (array1(kk,1)*t_rebuilt+(array1(kk, 4))); 
        aa_sig_combined_norm = aa_sig_combined_norm + aa_sig_rebuilt_norm;

        aa_sig_rebuilt_norm_bin = array1(kk, 2)*cos ((new_freq(zz,1))*array1(kk,1)*t_rebuilt+(array1(kk, 4))); %binural section
        aa_sig_combined_norm_bin = aa_sig_combined_norm_bin + aa_sig_rebuilt_norm_bin;
    end;

    %have it export to file 
    sig_norm=(aa_sig_combined_norm/max(abs(aa_sig_combined_norm))*.8); %normalize signal 
    sig_norm_bin=(aa_sig_combined_norm_bin/max(abs(aa_sig_combined_norm_bin))*.8); %normalize signal 


    wavwrite([sig_norm' sig_norm_bin'] ,fs,16,strcat(dirpathtmp,fn_LR_norm_bin)); %export file


end;

I do want to vectorize this for loop but at the moment I'm trying to fix the drift

Using 8000 as the sample frequency

Using 44100 as the sample frequency

share|improve this question
    
There's some information missing here. What is array1? Also, is there some reason you can't use interp1() rather than a for loop? –  Ryan J. Smith Apr 26 '13 at 21:23
    
I Added array1 but it's a very large function. I'm willing to try interp1 but I believe it ended up being extremely slow. the signals are vocal signals which are not simple signals. Trying to get some ideas what could be causing the drift The whole for loop is base on Amplitude*Cos(freq*time+phase) –  Rick T Apr 26 '13 at 21:30
    
If you just need to upsample, you could try the upsample() function. It just injects zeros and doesn't really do any interpolation but should preserve your original frequency components. –  Ryan J. Smith Apr 27 '13 at 0:11
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