Bisector energy and few distinct distances

Abstract

We introduce the bisector energy of an n-point set P in R2, defined as the number of quadruples (a,b,c,d) from P such that a and b determine the same perpendicular bisector as c and d. If no line or circle contains M(n) points of P, then we prove that the bisector energy is O(M(n)25n125+ε + M(n)n2).. We also prove the lower bound (M(n)n2), which matches our upper bound when M(n) is large. We use our upper bound on the bisector energy to obtain two rather different results: (i) If P determines O(n/ n) distinct distances, then for any 0<α 1/4, either there exists a line or circle that contains nα points of P, or there exist (n8/5-12α/5-ε) distinct lines that contain ( n) points of P. This result provides new information on a conjecture of Erdos regarding the structure of point sets with few distinct distances. (ii) If no line or circle contains M(n) points of P, then the number of distinct perpendicular bisectors determined by P is (\M(n)-2/5n8/5-ε, M(n)-1 n2\). This appears to be the first higher-dimensional example in a framework for studying the expansion properties of polynomials and rational functions over R, initiated by Elekes and R\'onyai.