hello
this is the poor man's solution with fminsearch (as I don't have the optimization toolbox but you can easily use fmincon instead of fminsearch
I had to modify your fit model
your version :
y1 = h1*exp(-log(2)/s1^2*(log(1+2*s1*(T-p1)/w1.^2)));
my version
y1 = h1*exp(-log(2)/s1^2*(log(1+2*s1*((T-p1)/w1).^2)));
so you get a peak centered around x= p1 ( your original model does not show any peak)
load('alp.mat')
load('T.mat')
x = T;
y = alp;
% curve fit using fminsearch
% We would like to fit the function
f = @(a,b,c,d,e,f,g,h,k,l,m,n,x) a*exp(-log(2)/b^2*(log(1+2*b*((T-c)/d).^2))) + e*exp(-log(2)/f^2*(log(1+2*f*((T-g)/h).^2))) + k*exp(-log(2)/l^2*(log(1+2*l*((T-m)/n).^2)));
obj_fun = @(par) norm(f(par(1),par(2),par(3),par(4),par(5),par(6),par(7),par(8),par(9),par(10),par(11),par(12),x)-y);
C1_guess = [0.005 0.5 275 50 0.004 0.5 315 30 0.0015 0.5 500 300];
sol = fminsearch(obj_fun, C1_guess); %
h1 = sol(1); % H1
s1 = sol(2); % S1
p1 = sol(3); % P1
w1 = sol(4); % W1
h2 = sol(5); % H2
s2 = sol(6); % S2
p2 = sol(7); % P2
w2 = sol(8); % W2
h3 = sol(9); % H3
s3 = sol(10); % S3
p3 = sol(11); % P3
w3 = sol(12); % W3
y_fit = f(h1,s1,p1,w1,h2,s2,p2,w2,h3,s3,p3,w3,x);
Rsquared = my_Rsquared_coeff(y,y_fit); % correlation coefficient
plot(x, y_fit, '-',x,y, 'r .-', 'MarkerSize', 15)
title(['Fit equation to data : R² = ' num2str(Rsquared) ], 'FontSize', 20)
xlabel('x data', 'FontSize', 20)
ylabel('y data', 'FontSize', 20)
legend('fit ','data');
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
function Rsquared = my_Rsquared_coeff(data,data_fit)
% R2 correlation coefficient computation
% The total sum of squares
sum_of_squares = sum((data-mean(data)).^2);
% The sum of squares of residuals, also called the residual sum of squares:
sum_of_squares_of_residuals = sum((data-data_fit).^2);
% definition of the coefficient of correlation is
Rsquared = 1 - sum_of_squares_of_residuals/sum_of_squares;
end
