# curve-fitting for linear and exponential function in Matlab

I have an array of data which, when plotted, looks wave.I need to determine the best fitting (linear and exponential) for these data and find the value of lambda 1,lambda 2 and tau in this function ((L=lambda 1*t+lambda 2*(1-exp(-t/tau). Some friends advice my to use((polyfit)) but I couldn't understanding the applicability of the command after reading the help file and searching in Google. Any help would be greatly appreciated. I will be grateful to you.

my attempt was as following:

``````%% data 1

t1      = file1 (:,1);
d1      = file1 (:,2);

% Then call plot()

plot(t1, d1, 'b*-', 'LineWidth', 2, 'MarkerSize', 15);
% Then get a fit

coeffs1 = polyfit(t1, d1, 1)
% Get fitted values
fittedX1 = linspace(min(t1), max(t1), 1001);
fittedY1 = polyval(coeffs1, fittedX1);
% Plot the fitted line
hold on;
plot(fittedX1, fittedY1, 'r-', 'LineWidth', 3);
hold off
hleg = legend('Data','lam*t + c','Location','northEast');

grid on;
title('Line fitting ','fontsize',13,'fontweight','b','color','k')
xlabel('Time ms','fontsize',13,'fontweight','b','color','k');
ylabel('Averge length','fontsize',13,'fontweight','b','color','k');
``````
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silly question: do you have the curve fitting toolbox? –  Benoit_11 Aug 13 at 13:08
NO, I don't have this book Benoit_11. If you have it could you send it to me. –  Abdulrahman Aug 13 at 13:16
Actually it's not a book but a Toolbox that you can purchase from The Mathworks and run with Matlab; there are a few functions that would be useful to you. That's fine though there should be a workaround without this Toolbox. –  Benoit_11 Aug 13 at 13:18
So what is your question? You showed the code but you did not say what is wrong with what comes out of it. –  PetrH Aug 13 at 13:27
The code looks fine to me, although here `coeffs1 = polyfit(t1, d1, 1)` you ask for a polynomial of degree one (ie straight line) to be fitted which will clearly not give you very good fit if the data has a wave pattern. –  PetrH Aug 13 at 13:31

If you have access to the Optimization toolbox, you can formulate this problem, such that it can be solved with fminsearch(). Here is how it can be done: The parameter to optimize (lambda1, lambda2 and tau) are stored in one parameter-vector, which will be used by the fit_function, which is the function that you proposed.

``````function main

% some data
t = sort(rand(50,1)*10);
lambda1 = 0.5;
lambda2 = 1;
tau = 2.0;
par = [lambda1, lambda2, tau];
y = fit_function(t, par) + (rand(size(t))-0.5)*0.2;

par0 = [1,2,3]; % initial guess
par_fit = fminsearch(@objFun, par0);

% nested objective function, this one will be minimized
function e = objFun(par)
yfitted = fit_function(t, par);
e = sum((yfitted-y).^2);
end

% plotting some results
figure
plot(t,fit_function(t,par),'k-')
hold on
plot(t,y,'ko')
plot(t,fit_function(t,par_fit),'rx-')
legend('original','noisy','optimization')
par
par_fit

end

function yfitted = fit_function(t, par)
% y = lambda1*t + lambda2*(1-exp(-t/tau))
lambda1 = par(1);
lambda2 = par(2);
tau = par(3);
yfitted = lambda1*t + lambda2*(1-exp(-t/tau));
end
``````

The result looks like this: The parameters i used for the unnoisy data and the parameters which came out of the optimization are like this

``````par =

0.5000    1.0000    2.0000

par_fit =

0.4949    1.0433    2.1792
``````

Best, Nras.

``````function main
%% ----- DATA -----
t = file1(:,1);
y = file1(:,2);

%% ----- OPTIMIZATION -----
par0 = [1,2,3]; % initial guess <--- Here you have to make a good guess
par_fit = fminsearch(@objFun, par0);

%% ----- OBJECTIVE FUNCTION (will be minimized) -----
function e = objFun(par)
yfitted = fit_function(t, par); % result of model function with current parameter
e = sum((yfitted-y).^2); % minimize squared distance between model and observation
end

%% ----- VSIUALIZING RESULTS ----- %
figure
plot(t,y,'ko')
hold on
plot(t,fit_function(t,par_fit),'rx-')
legend('original','optimization')
end

%% ----- MODEL FUNCTION ----- %
function yfitted = fit_function(t, par)
% the model function reads as:  y = lambda1*t + lambda2*(1-exp(-t/tau))
lambda1 = par(1);
lambda2 = par(2);
tau = par(3);
yfitted = lambda1*t + lambda2*(1-exp(-t/tau));
end
``````
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Thanks Nras....I have an anonymous Function> I do not know the value of lambda1, lambda2 and tau –  Abdulrahman Aug 15 at 9:32
@Abdulrahman Well that is the problem, if you knew the values for lambda1, lambda2 and tau, then you would not have to make an optimization. I just set some values for lambda1, lambda2 and tau to generate some data, but you already have some data. You just need to give an initial guess `par0` and the optimizer will try to get an optimal solution from there. –  Nras Aug 15 at 9:36
Thanks for your replay. Do you mean I have to set par0=[1,2,3];and create my function yfitted = lambda1*t + lambda2*(1-exp(-t/tau));. In fact,I get lost –  Abdulrahman Aug 15 at 9:41
You just have to replace the part below the line `% some data` with your own data, which is stored in `t1` and `d1`. Since i did not have access to that data, i created my own data in that section and called it `t` and `y`, which was more intuitive. You can play around using different intitial gueses for `par0`, yes. They could be of competely different order of magnitude for your real data. –  Nras Aug 15 at 9:50
Thanks for your cooperation with me,could you write the code according to my data. I think there are many variable need to change. –  Abdulrahman Aug 15 at 10:21