I'm solving a 600k x 200 matrix using linear regression now. This is problematic, because I can't add much more coefficients (columns) due to RAM constraints. I got the tip to look into solving the normal equations, which would reduce my problem to 200x200. Does anyone here have a good reference on how to do that? (Theoretical/mathematical is good, no need for a MATLAB tutorial)
@AnderBiguri That could work... I need to go to "only" degree and order 15 or so for the spherical harmonics. Not the 134 I needed in the previous problem :P
the good thing is it doesnt matter. if you input A as a function handle, it can be whatever, as long as it inputs outputs a particular size of matrices
if you write a generic form for b=A(x) fucntion, then you can try 5 or 5000 order polinomials :D
Which has 2S_max 2P_max ((Nmax+1) ^2-1) coefficients
we'd like Smax = 4, Pmax = 4, Nmax = 15
So in this case the polynomial order isn't that high. (That was a few weeks ago, where I had the formula, but wanted it symbolic, rather than numeric for each of my 200M measurements)
Basically Ynm are spherical harmonics (spatial patterns on a sphere), P modulates a daily frequency (makes the planet go round), S determines the season (Takes care of the ellipticity of Mars' orbit). We want \tilde \iota of course
@AnderBiguri Yup. We solve the real-valued problem, thus loads of cos/sin involved
So the Bs on the left are the vector of observations, we want iota, our unknown, and we know everything inbetween. We choose a certain set of p,n,m (and S if you multiply over that as well), know where the satellite was, i.e. we know r,theta,phi,t. That means that everything between the = and the iota can be calculated, leading to loads of columns.
It's actually not too bad, except that the derivatives of the associated Legendre polynomial aren't built-in MATLAB. Otherwise it's just a bunch of loops recursing over the Legendre polynomial and adding a few cos/sin terms ;)
@AnderBiguri I can't find it right now: But I've heard that that could sometimes cause issues where you end up moving in a circle, whereas with a little bit more randomness you can avoid that with a higher probability or something like that
@flawr yes its correct, but you also introduce unecesary statistics. OS-stuff is good when you want fast convergence to tthe solution, but indeed, it may have bias, or cycle trhough the solutions. Depends on the application I guess. In medical imaging, OS-algorithms are the norm on some machines