On Semialgebraic Range Reporting

Abstract

In the problem of semialgebraic range searching, we are to preprocess a set of points in RD such that the subset of points inside a semialgebraic region described by O(1) polynomial inequalities of degree can be found efficiently. Relatively recently, several major advances were made on this problem. Using algebraic techniques, "near-linear space" structures [AMS13,MP15] with almost optimal query time of Q(n)=O(n1-1/D+o(1)) were obtained. For "fast query" structures (i.e., when Q(n)=no(1)), it was conjectured that a structure with space S(n) = O(nD+o(1)) is possible. The conjecture was refuted recently by Afshani and Cheng [AC21]. In the plane, they proved that S(n) = (n+1 - o(1)/Q(n)(+3)/2) which shows (n+1-o(1)) space is needed for Q(n) = no(1). While this refutes the conjecture, it still leaves a number of unresolved issues: the lower bound only works in 2D and for fast queries, and neither the exponent of n or Q(n) seem to be tight even for D=2, as the current upper bound is S(n) = O(nm+o(1)/Q(n)(m-1)D/(D-1)) where m=D+D-1 = (D) is the maximum number of parameters to define a monic degree- D-variate polynomial, for any D,=O(1). In this paper, we resolve two of the issues: we prove a lower bound in D-dimensions and show that when Q(n)=no(1)+O(k), S(n)=(nm-o(1)), which is almost tight as far as the exponent of n is considered in the pointer machine model. When considering the exponent of Q(n), we show that the analysis in [AC21] is tight for D=2, by presenting matching upper bounds for uniform random point sets. This shows either the existing upper bounds can be improved or a new fundamentally different input set is needed to get a better lower bound.