Stable complete coordinates for multisets of points via basic r-symmetric tropical polynomials

Abstract

A multiset of n unordered points in Rr -- a point cloud, or, for r=2, a persistence barcode of birth-death pairs -- is a point of the orbit space Rnr/Sn for the symmetric group Sn permuting the rows of an n × r matrix; a separating family of invariants on this space is exactly a complete set of permutation-independent coordinates. We provide one that is explicit, small, and stable, in the max-plus (tropical) setting: for all n ≥ 1 and r ≥ 1, the n+rr basic r-symmetric tropical polynomials, of degree at most n, separate the orbits of Sn on Rnr. This settles in full a problem left open in [Kubo, J. Pure Appl. Algebra 223 (2019) 72-85], where separation was known only for r=2 and special cases of r ≥ 3, and yields a family far smaller and of lower degree than the general separating sets from Derksen's recent theory of tropical invariants for permutation actions (nr + (nr)!/n! invariants of degree O(n2 r2)). The proof is elementary and constructive: the basic values are identified with a transportation problem, and the multiset is recovered from the dual by an explicit algorithm. We further show the coordinate map is a bi-Lipschitz embedding for all n and r, being an injective max filter bank (via the bi-Lipschitz theory of max filtering), with an explicit Lipschitz constant for the forward bound and a fully explicit, dimension-free distortion when r=1. Finally we determine when the pairwise values suffice (exactly n ≤ 3) and show that invariants on at least three columns and of degree less than n are necessary in general, the obstruction being a standard non-uniqueness configuration from discrete tomography.