I have a question with the classical gradient descent algorithm. Recently I want to implement a function fitting program provided the observed data as well as the parameters of the function is given. The method I have used is the gradient descent algorithm as the derivatives of the function are available. Suppose the function parameters are given, I can create the simulated data based on the function:
clean; rng('default'); rng(54321); low_value = 15; high_value = 200; dis_value = (high_value-low_value)/2; central_value = (low_value+high_value)/2; x = 1:55; central_pixel = (1+length(x))/2; delta = 3; len = length(x); y_true = dis_value*erf((x-central_pixel)./delta)+central_value; y = y_true + randn(1,len); figure;plot(x,y,'b*'); hold on; plot(x,y_true,'r');
The figure below shows the simulated data (blur asterisk points )as well as the potential function (in red): As you can see from the figure there are two parameters to estimate in this example, one is the center point position p and the other is the standard derivation delta, and the function is written as
where A and B can be regarded as known. Then if I want to use gradient descent algorithm, I should do two things: one is define the derivatives of the function for the two unknown parameters (p and delta) respectively, and the other is to invoke the gradient descent algorithm. However, what I have found confusing is that during the iterative procedure one of the estimated parameters (delta) does not go to the right direction all the time:
I do notice, however, that object function (the sum of the square distance between the fitting point and the estimated function) is always becoming smaller:
My question is then why the solutions do not always go to the right direction even though in the end they can reach the right place. Thanks!