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So I have had a few posts the last few days about using MatLab to perform a convolution (see here). But I am having issues and just want to try and use the convolution property of Fourier Transforms. I have the code below: width = 83.66;

x = linspace(-400,400,1000);

      a2 =  1.205e+004  ;
       al =  1.778e+005  ;
       b1 =       94.88  ;
       c1 =       224.3  ;
       d =       4.077  ;

measured =  al*exp(-((abs((x-b1)./c1).^d)))+a2;

%slit
rect = @(x) 0.5*(sign(x+0.5) - sign(x-0.5));
rt = rect(x/width);


subplot(5,1,1);plot(x,measured);title('imported data-super gaussian')
subplot(5,1,2);plot(x,(real(fftshift(fft(rt)))));title('transformed slit')
subplot(5,1,3);plot(x,rt);title('slit')

u = (fftshift(fft(measured)));
l = u./(real(fftshift(fft(rt))));
response = (fftshift(ifft(l)));

subplot(5,1,4);plot(x,real(response));title('response')

%Data Check
check = conv(rt,response,'full');
z = linspace(min(x),max(x),length(check));
subplot(5,1,5);plot(z,real(check));title('check')

My goal is to take my case, which is $measured = rt \ast signal$ and find signal. Once I find my signal, I convolve it with the rectangle and should get back measured, but I do not get that.

I have very little matlab experience, and pretty much 0 signal processing experience (working with DFTs). So any advice on how to do this would be greatly appreciated!

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1 Answer 1

up vote 2 down vote accepted

After considering the problem statement and woodchips' advice, I think we can get closer to a solution.

Input: u(t)

Output: y(t)

If we assume the system is causal and linear we would need to shift the rect function to occur before the response, like so:

rt = rect(((x+270+(83.66/2))/83.66));
figure; plot( x, measured, x, max(measured)*rt )

Shifted Input

Next, consider the response to the input. It looks to me to be first order. If we assume as such, we will have a system transfer function in the frequency domain of the form:

H(s) = (b1*s + b0)/(s + a0)

You had been trying to use convolution to and FFT's to find the impulse response, "transfer function" in the time domain. However, the FFT of the rect, being a sinc has a zero crossing periodically. These zero points make using the FFT to identify the system extremely difficult. Due to:

Y(s)/U(s) = H(s)

So we have U(s) = A*sinc(a*s), with zeros, which makes the division go to infinity, which doesn't make sense for a real system.

Instead, let's attempt to fit coefficients to the frequency domain linear transfer function that we postulate is of order 1 since there are no overshoots, etc, 1st order is a reasonable place to start.

EDIT I realized my first answer here had a unstable system description, sorry! The solution to the ODE is very stiff due to the rect function, so we need to crank down the maximum time step and use a stiff solver. However, this is still a tough problem to solve this way, a more analytical approach may be more tractable.

We use fminsearch to find the continuous time transfer function coefficients like:

function x = findTf(c0,u,y,t)
  % minimize the error for the estimated
  % parameters of the transfer function
  % use a scaled version without an offset for the response, the
  % scalars can be added back later without breaking the solution.
  yo = (y - min(y))/max(y);
  x = fminsearch(@(c) simSystem(c,u,y,t),c0);
end

% calculate the derivatives of the transfer function
% inputs and outputs using the estimated coefficient
% vector c
function out = simSystem(c,u,y,t)
  % estimate the derivative of the input
  du = diff([0; u])./diff([0; t]);
  % estimate the second derivative of the input
  d2u = diff([0; du])./diff([0; t]);
  % find the output of the system, corresponds to measured
  opt = odeset('MaxStep',mean(diff(t))/100);
  [~,yp] = ode15s(@(tt,yy) odeFun(tt,yy,c,du,d2u,t),t,[y(1) u(1) 0],opt);
  % find the error between the actual measured output and the output
  % from the system with the estimated coefficients
  out = sum((yp(:,1) - y).^2);
end

function dy = odeFun(t,y,c,du,d2u,tx)
  dy = [c(1)*y(3)+c(2)*y(2)-c(3)*y(1); 
        interp1(tx,du,t);
        interp1(tx,d2u,t)];
end

Something like that anyway should get you going.

x = findTf([1 1 1]',rt',measured',x');
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You lost be at the system transfer function H –  yankeefan11 Jul 2 '13 at 15:21
    
So will the findTf function find H(s) ? I have never heard of transfer functions. In doing a quick search it seems to involve LaPlace transform. Is this where the idea of using a first order comes into play? –  yankeefan11 Jul 3 '13 at 13:36
    
Yes, it will try to find the function H(s), if you've never heard of Laplace transforms and transfer functions, this is not the solution for you. I'm surprised you've been introduced to convolution, Fourier transforms, but not transfer functions. –  macduff Jul 3 '13 at 13:55
    
Yeah. I have not been introduced to transfer functions. I am familiar with LaPlace transforms, but only in a differential equation setting. I am looking into them more as a possible solution. –  yankeefan11 Jul 3 '13 at 13:59
    
I do not understand why we choose first order. And then also, I just ran the code you have to see what the result looks like, and it is taking a REALLY long time. –  yankeefan11 Jul 3 '13 at 14:18

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