A symmetric determinantal lower bound for diagonal power sums via polar degree

Abstract

The symmetric determinantal complexity sdc(f) of a polynomial f is the least m such that f = det(M) for an m x m symmetric matrix M of affine-linear forms. We prove, over the complex numbers, that sdc(sumi=1n xin) >= (1/(2e) - o(1)) n2. This is a symmetric companion to the author's non-symmetric polar-degree preprint (arXiv:7680505); the method parallels that work, but the proof here is self-contained and redoes the load-bearing local incidence analysis in the symmetric setting. The general theorem: if X = V(f) in PN-1 is a smooth degree-d hypersurface, N >= 3, and f = det(A0 + sum xi Ai) with all Ai symmetric of size m, then the top polar degree d(d-1)N-2 is at most 2N-2 C(m, N-1). The proof uses the symmetric rank-one kernel incidence M(z,x) u = 0. At a genuine polar point M has rank m-1, and a symmetric Schur-complement normal form eliminates the unique kernel line scheme-theoretically; on the resulting local graph the lifted conormal forms uT Ai u are a common unit multiple of the partials di f, so the lifted polar equations cut the ordinary polar slice up to units and each genuine lifted polar point is a zero-dimensional isolated solution. Multihomogeneous Bezout on PN x Pm-1 then yields the bound 2N-2 C(m, N-1). For Fn = sum xin this gives the constant 1/(2e). More generally, for FN,d = sumi=1N xid the same theorem gives sdc(FN,d) >= (1/(2e) - oN(1)) N(d-1) as N -> infinity. We give an explicit symmetric representation of FN,d of size 2N(d+1)+1, so the diagonal bounds are non-vacuous and tight up to a constant. The result is for exact symmetric determinantal complexity in characteristic zero; it is not a border statement and not a uniform positive-characteristic theorem.