The Distributional Tail of Worst-Case Quickselect

Abstract

We study the almost surely finite random variable S defined by the distributional fixed-point equation \[ S d= 1 + \US', (1-U)S''\, U Unif(0,1), \] where S' and S'' are independent copies of S, independent of U. This random variable arises as the almost sure limit of the normalized worst-case number of key comparisons used by classical Quickselect with uniformly chosen pivots in the model of Devroye. Our first contribution concerns the right tail of S. We prove explicit one-sided bounds for the rate function - P(S>t) and, in particular, identify its first-order asymptotic growth: \[ - P(S>t) = t t + O(t t), t ∞. \] The argument combines a binary-search-tree embedding and a one-level second-moment method with a moment-generating-function comparison inspired by ideas of Alsmeyer and Dyszewski for the nonhomogeneous smoothing transform. As a byproduct, we obtain an explicit pointwise Chernoff majorant for the tail. Our second contribution is a distribution-function scheme for deriving explicit upper bounds on E[S]. Starting from the fixed-point equation at the level of the distribution function, we construct an order-preserving lower iteration and a conservative mesh discretization suited to computer-assisted upper bounds on the mean. We illustrate the latter numerically in floating-point arithmetic, but do not pursue a certified numerical proof here.