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I'm doing some data analysis. I have already done some work fitting a lot of data and I was recommended to save all these fits into a cell structure. So far so good. I have 65 pieces of data and they have all been broken into 13 chunks each and each chunk has been fitted to a sine function and put into a cell i call fits. So the cell is 65x13. What I want to do know is to find the mean of a specific fitvalue for each row and calculate the std and i also want numbers that differ too much to be completely removed from. So i have tried various for loops to do this:

nrk is set to be 65*13 = 845

for ll=1:nrk
    frequency(1,ll) = fits{1:size(hit,1),1:FitNums}.w./(2.*pi);
end

and stuff like

for ss=1:size(hit,1)
    for pp=1:FitNums
        for ll=1:klip
            frequency(1,ll) = fits{ss,pp}.w./(2.*pi);
        end
    end
end

And both of these end up putting only the last value fits{65,13}.w./(2.*pi)=937.3071 into the vector, frequency.

And i haven't even started trying to sort the bad values out. What would be most optimal would probably be to divide the cell into 65 (Which is size(hit,1)) row vectors and operate with them individually giving more control and then joining the results in one last vector.

To sum up. I'm doing an experiment where i am measuring the sound of different events. I'm looking the dominant tone of the different events. I load a wav file into Matlab. I then break the wav file into 65 pieces, i won't go into detail as it is irrelevant, and each of these 65 pieces contains the sound of an event. By zooming in on the data i noticed that even though it is overall a dampened sine signal it can be represented as a series of smaller sine signals with no dampening. So i decided to break each of the 65 pieces into 13 smaller pieces each, giving a total of 845 pieces. I then fitted each little piece to a sine function using

dt = 1/44100; %from sampling freq

kk = 150; %number of points i want the smaller pieces to be
fits=cell(size(hit,1),round(size(hit,2)/kk));
gofs=cell(size(hit,1),round(size(hit,2)/kk));

nrk = FitNums.*size(hit,1); 
frequency = zeros(klip);

for ii=1:size(hit,1)

    FitNums = round(size(hit(ii,:),2)/kk);
    xx = linspace(0,dt*kk,kk);

    for jj=1:FitNums
        yytemp = hit(ii,1+(jj-1)*kk:jj*kk);

        [xData, yData] = prepareCurveData( xx, yytemp );

        % Set up fittype and options.
        ft = fittype( 'a*sin(w*x+p)', 'independent', 'x', 'dependent', 'y' );
        opts = fitoptions( ft );
        opts.Display = 'Off';
        opts.Lower = [0 -pi 0];
        opts.StartPoint = [0.4003 0.1419 6.15e3];
        opts.Upper = [Inf pi 2e5];

        % Fit model to data.
        [fitresult, gof] = fit( xData, yData, ft, opts );
        %disp(fitresult);
        fits{ii,jj} = fitresult;
        gofs{ii,jj} = gof;
    end
end

So fits contains 65 rows, representing each of the sound events, with 13 columns, 13 being the number of pieces one sound event is broken into. So for example fits(1,:) represents the first sound event.

The problem now is, that i haven't worked with cells before and don't really have an intuition for them. But what I am trying to do is:

  • Convert from angular frequency to frequency by using the parameter w from a fit and dividing by 2pi like with frequency(1,ll) = fits{1:size(hit,1),1:FitNums}.w./(2.*pi);
  • This will give us 13 frequencies for each sound event and the mean and std must be taken so that we get one frequency representing a sound event.
  • There are points that differ way to much from the others and these needs to be removed before taking mean and std. For example fits(1,:) might give something like this: 1000 980 1020 1000 1000 1010 2400 990 1000 1010 1000 1020 1000. The number 2400 has to be removed because it will give a wrong mean and std. It's alright to remove numbers that are too high as i have done other experiments determing resonance frequency and alike.

Solved the problem with

freqtemp = zeros(1,FitNums);
frekvenser = cell(size(hit,1),1);

for ss = 1:size(hit,1)
    for jj = 1:FitNums
        freqtemp(jj) = fits{ss,jj}.w./(2*pi);
    end
    frekvenser{ss} = freqtemp;
end

Which gives a nice cell containing 65 1x13 doubles which are easily handled for further analysis.

Thanks a lot.

share|improve this question
    
Perhaps I'm missing something, but fits{1:size(hit,1),1:FitNums}.w./(2.*pi) doesn't vary with the loop –  Rasman Mar 2 '13 at 19:42
    
1:size(hit,1) and 1:FitNums should run from, respectively, 1:65 and 1:13? –  Simon G. F. Mar 2 '13 at 19:49
    
Oh you are right.. Thats one flaw. But frequency(1,ll) = fits{ss,pp}.w./(2.*pi); should change. –  Simon G. F. Mar 2 '13 at 19:53
    
No, not really, as fits{ss,pp}.w./(2.*pi) doesn't vary with ll/ Basically, what you're doing is frequency(1,:) = fits{size(hit,1),FitNums}.w./(2.*pi); –  Rasman Mar 2 '13 at 20:06
    
I thought the for loops would do that. How do i get around doing that? –  Simon G. F. Mar 2 '13 at 20:12

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