A geometry in the set of solutions to ill-posed linear problems with box constraints: Applications to probabilities on discrete sets

Abstract

When there are no constraints upon the solutions of the equation A= y, where A is a K× N-matrix, ∈RN and y∈RK a given vector, the description of the set of solutions as y varies in RK is well known. But this is not so when the solutions are required to satisfy ∈ KΠi≤ j≤ N [aj,bj], for finite aj≤ bj: 1≤ j≤ N. Here we provide a description of the set of solutions as a surface in the constraint set, parameterized by the Lagrange multipliers that come up in a related optimization problem in which A = y appears as a constraint. It is the dependence of the Lagrange multipliers on the data vector y that determines how the solution changes as the datum changes. The geometry on the solutions is inherited from a Riemannian geometry on the set of constraints induced by the Hessian of an entropy of the Fermi-Dirac type which is the objective in the restatement of the optimization problem mentioned above. We prove that the set of solutions is contained in (A) in the metric defined as the Hessian of the entropy.