yBlue be the coordinates of the blue dots (n-by-1 vectors), and
yRedFun be the spline approximation function, so
yRedFun(x) will return the interpolated red line at
yRedFun may be an anonymous function handle
@(x) ppval(pp,x) . Maybe you will need to slightly extrapolate the red line so the yRedFun will be defined on all the xBlue .
We now may define a minimization function:
cost = @(deltaX) norm( yBlue - arrayfun(yRedFun, xBlue + deltaX) )
Its minimum can be found by
deltaX = fminsearch(cost, 0) or
deltaX = fzero(cost, 0).
Though this may be a too general approach, if fast performance is not needed, it should be OK. Also, as the fit between blue and red probably is not exact, the method formalizes the norm you are trying to minimize.
If performance is needed, the next algorithm may be used:
function deltaX = findDeltaX(xBlue, yBlue, yRedFun, precision)
deltaX = 0; % total delta
deltaDeltaX = Inf; % delta at each iteration
yRedFunDer = fnder(yRedFun);
while(abs(deltaDeltaX) > precision)
xRed = xBlue + deltaX;
yRed = fnval(yRedFun, xRed);
yRedDer = fnval(yRedFunDer, xRed);
deltaDeltaX = yRedDer \ (yRed - yBlue);
deltaX = deltaX + deltaDeltaX;
Points with low derivative may reduce precision. On the first iteration you may pick
N points with highest derivative and drop all the others. This will also improve performance.
[~, k] = sort(abs(yRedDer), 'descend');
k = k(1:N);
yRedDer = yRedDer(k);
xBlue = xBlue(k);
yBlue = yBlue(k);