Geometry-Driven Conditioning of Multivariate Vandermonde Matrices in High-Degree Regimes

Abstract

We study multivariate monomial Vandermonde matrices VN(Z) with arbitrary distinct nodes Z=\z1,…,zs\⊂ B2n in the high-degree regime N s-1. Introducing a projection-based geometric statistic -- the max-min projection separation (Z,j) and its minimum (Z)=j(Z,j) -- we construct Lagrange polynomials Qj∈ PNn with explicit coefficient bounds \|Qj\|∞ s(4n(Z,j))s-1. These polynomials yield quantitative distance-to-span estimates for the rows of VN(Z) and, as consequences, σ(VN(Z)) (Z)s-1(4n)s-1 ss (n,N), (n,N)=N+n N, and an explicit right inverse VN(Z)+ with operator-norm control \|VN(Z)+\| s3/2(n,N)(4n(Z))s-1. Our estimates are dimension-explicit and expressed directly in terms of the local geometry parameter (Z); they apply to every distinct node set Z⊂ B2n without any a priori separation assumptions. In particular, VN(Z) has full row rank whenever N s-1. The results complement the Fourier-type theory (on the complex unit circle/torus), where lower bounds for σ hinge on uniform separation or cluster structure; here stability is quantified instead via high polynomial degree and the projection geometry of Z.