Bounds on the Number of Modes of a Gaussian Mixture Density

Abstract

We derive explicit upper bounds for the number of nondegenerate critical points of a k-component Gaussian mixture density in Rd, and the number of modes when the modal set is finite, together with lower bounds. By normalizing the critical-point equations by a reference component, for k2 we get the direct Pfaffian bound \[ Uhet(d,k)=2\,d+k-12(d+2(d,k-1)+1)k-1. \] For the same parameter range, an exact elimination augmented by an algebraic reciprocal variable gives the alternative bound \[ Uaug(d,k)= 2k-12(d+1)((2k-1)d+2k-1)k-1. \] Thus, for k2, the best critical-point bound is their minimum. A Morse-theoretic argument improves the corresponding finite-mode upper bound to \[ \Uhet(d,k),Uaug(d,k)\+12. \] In the homoscedastic case, for k2, the direct bound improves to \[ Uhom(d,k)=2\,d+k-12(d+(d,k-1)+1)k-1, \] an affine-rank reduction replaces d by the affine rank of the component means, and an augmented homoscedastic reduction gives the dimension-free bound \[ Uaug,hom(k)=2k-12+1(2k)k-1. \] On the lower-bound side, for d,k 2 we obtain \[ Lbin(d,k)=k+2 r (d,k)kr, \] together with a padding-product family that in particular implies the linear lower bound d+k-1, and a seed-closure principle that packages product and padding constructions. We further give explicit bounds for the number of connected components of the critical set.