Approximating Pointwise Products of Laplacian Eigenfunctions

Abstract

We consider Laplacian eigenfunctions on a d-dimensional bounded domain M (or a d-dimensional compact manifold M) with Dirichlet conditions. These operators give rise to a sequence of eigenfunctions (e) ∈ N. We study the subspace of all pointwise products An = span \ ei(x) ej(x): 1 ≤ i,j ≤ n\ ⊂eq L2(M). Clearly, that vector space has dimension dim(An) = n(n+1)/2. We prove that products ei ej of eigenfunctions are simple in a certain sense: for any > 0, there exists a low-dimensional vector space Bn that almost contains all products. More precisely, denoting the orthogonal projection Bn:L2(M) → Bn, we have ∀~1 ≤ i,j ≤ n~ \|eiej - Bn( ei ej) \|L2 ≤ and the size of the space dim(Bn) is relatively small: for every δ > 0, dim(Bn) M,δ -δ n1+δ. We obtain the same sort of bounds for products of arbitrary length, as well for approximation in H-1 norm. Pointwise products of eigenfunctions are low-rank. This has implications, among other things, for the validity of fast algorithms in electronic structure computations.