On the 2-Central Path Problem

Abstract

In this paper we consider the following 2-Central Path Problem (2CPP): Given a set of m polygonal curves \(\mathcal{P} =\{P_1,P_2,\ldots,P_m\}\) in the plane, find two curves P _u and P _l , called 2-central paths, that best represent all curves in \(\mathcal{P}\). Despite its theoretical interest and wide range of practical applications, 2CPP has not been well studied. In this paper, we first establish criteria that P _u and P _l ought to meet in order for them to best represent \(\mathcal{P}\). In particular, we require that there exists parametrizations f _u (t) and f _l (t) (t ∈ [a,b]) of P _u and P _l respectively such that the maximum distance from {f _u (t), f _l (t)} to curves in \(\mathcal{P}\) is minimized. Then an efficient algorithm is presented to solve 2CPP under certain realistic assumptions. Our algorithm constructs P _u and P _l in O(nmlog⁴ n 2^α(n) α(n)) time, where n is the total complexity of \(\mathcal{P}\) (i.e., the total number of vertices and edges), m is the number of curves in \(\mathcal{P}\), and α(n) is the inverse Ackermann function.Our algorithm uses the parametric search technique and is faster than arrangement-related algorithms (i.e. Ω(n ²)) when m ≪ n as in most real applications.

This research was partially supported by NSF through a CAREER award CCF-0546509 and grants IIS-0713489 and IIS-1115220.