In Matlab, you do numerical optimization. That means that you don't have to worry about the analytical form of your objective function. Instead, you need to write an objective function that creates, using the optimization parameters, for every value
x of your data an
y-value that you can then compare with your input data.
With linear and non-linear constraints, you can use FMINCON to solve your problem.
I'm not entirely sure I understand what you want to optimize (sorry, it's a bit early), but for the sake of an example, let me assume that you have a vector with x-values
xdata and a vectory with y-values
ydata to which you want to fit a "stair-function". You know how many steps there are, but you do not know where they're placed. Also, you know that the sum of the step locations has to be 5 (linear equality constraint).
You start out by writing your objective function, the output of which you want to get as close to 0 as possible. This could be the squared sum of the residuals (i.e. the difference between the real y-values and the estimated y-values). For my convenience, I won't define the step locations via linear equations, but I'll set them directly instead.
function out = objFun(loc,xdata,ydata)
%#OBJFUN calculates the squared sum of residuals for a stair-step approximation to ydata
%# The stair-step locations are defined in the vector loc
%# create the stairs. Make sure xdata is n-by-1, and loc is 1-by-k
%# bsxfun creates an n-by-k array with 1's in column k wherever x>loc(k)
%# sum sums up the rows
yhat = sum(bsxfun(@gt,xdata(:),loc(:)'),2); %'# SO formatting
%# sum of squares of the residuals
out = sum((ydata(:)-yhat).^2);
Save this function as
objFun.m in your Matlab path. Then you define
ydata (or load it from file), make an initial guess for
loc (k-by-1 array), and the array
Aeq for the linear equality contstraint such that
[1 1 1] in case you have 3 steps), and write
locEst = fmincon(@(u)objFun(u,xdata,ydata),locInitialGuess,,,Aeq,5);
This will estimate the location of the steps. Instead of the two empty brackets you can add inequality constraints, and the 5 is because I assumed the equality constraint evaluates to 5.