@LuisMendo That’s true also for the traveling salesman problem. You have the salesman traverse a list of pointers to cities, instead of the actual cities. O(1) solution I think.
Another hypothetical question: If we want to warp an image, we can use a deformation field (i.e. a vector per pixel), or we could reduce the number of parameters by using a handful of control points and e.g. splines to interpolate.
But are there other ways to parametrize deformations that are area-preserving?
if you are minimizing something, I am not sure you can make it a hard constraint, you start having ugly norms
you'd need some sort of non-linear norm I think, L_0 or something, which is ugly AF for traditional optimizations
The specific paper I was thinking about is: Emond, Elise C., et al. "Improved PET/CT Respiratory Motion Compensation by Incorporating Changes in Lung Density." IEEE Transactions on Radiation and Plasma Medical Sciences 4.5 (2020): 594-602.
@AnderBiguri I was just thinking: In order to preserve some smoothness you can still use the displacement field appraoch just with some regularization.
But for the displacement field it is easy to compute the area-preserved-ness
but some of the smoothness comes relatively "cheap", as if you define your DVF as a spline on spaced control points, you are already imposing implicit regularization on smoothness
then you can just have some L2-norm on the gradient, if you want, but in parctical terms it does not need to have big regularization parameter
@flawr this sounds... reasonable, yet complicated?
I was in this talk the other day, and someone said "In this work, we study nerual networks in Banach spaces, because everything is much easier to understand if its infinite dimensional" and he genuinelly meant it
well I guess, except neural networks are almost inherently discrete operations
what is even a continous neural netowrk
ugh, trying to get my head around some maths and this Fenchel conjugate keeps appearing and does not matter how much I read about it, I don't fucking get it
yeah, its one of those magic steps where they go "thanks to the Fenchel conjugate, we can do eq(5)" and I either just beleive it or learn the heck it is
my problem is that mathematicians love to write the algorithms in a generic manner, but I have no idea how to convert some of that to human code
Its all "generic function f that is convex" -> "and the solution to CT recon is...". Wait wait, what is f in this case? "exercise to the fucking reader"