Computing intrinsic volumes of sublevel sets and applications
Abstract
Intrinsic volumes are fundamental geometric invariants generalizing volume, surface area, and mean width for convex bodies. We establish a unified Laplace-Grassmannian representation for intrinsic and dual volumes of convex polynomial sublevel sets. More precisely, let f be a convex d-homogeneous polynomial of even degree d 2 which is positive except at the origin. We show that the intrinsic and dual volumes of the sublevel set [f 1] admit Laplace-type integral formulas obtained by averaging the infimal projection and restriction of f over the Grassmannian. This explicit representation yields three main consequences: (1) L\"owner--John-type existence and uniqueness results extending beyond the classical volume case; (2) a block decomposition principle describing factorization of intrinsic volumes under direct-sum splitting; (3) a coordinate-free formulation of Lipschitz-type lattice discrepancy bounds. These formulas enable analytic treatment of a broad class of geometric quantities, providing direct access to variational and arithmetic applications as well as new structural insights.
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