English

Hidden Hamiltonian Cycle Recovery via Linear Programming

Discrete Mathematics 2018-04-18 v1 Data Structures and Algorithms Probability Machine Learning

Abstract

We introduce the problem of hidden Hamiltonian cycle recovery, where there is an unknown Hamiltonian cycle in an nn-vertex complete graph that needs to be inferred from noisy edge measurements. The measurements are independent and distributed according to \calPn\calP_n for edges in the cycle and \calQn\calQ_n otherwise. This formulation is motivated by a problem in genome assembly, where the goal is to order a set of contigs (genome subsequences) according to their positions on the genome using long-range linking measurements between the contigs. Computing the maximum likelihood estimate in this model reduces to a Traveling Salesman Problem (TSP). Despite the NP-hardness of TSP, we show that a simple linear programming (LP) relaxation, namely the fractional 22-factor (F2F) LP, recovers the hidden Hamiltonian cycle with high probability as nn \to \infty provided that αnlogn\alpha_n - \log n \to \infty, where αn2logdPndQn\alpha_n \triangleq -2 \log \int \sqrt{d P_n d Q_n} is the R\'enyi divergence of order 12\frac{1}{2}. This condition is information-theoretically optimal in the sense that, under mild distributional assumptions, αn(1+o(1))logn\alpha_n \geq (1+o(1)) \log n is necessary for any algorithm to succeed regardless of the computational cost. Departing from the usual proof techniques based on dual witness construction, the analysis relies on the combinatorial characterization (in particular, the half-integrality) of the extreme points of the F2F polytope. Represented as bicolored multi-graphs, these extreme points are further decomposed into simpler "blossom-type" structures for the large deviation analysis and counting arguments. Evaluation of the algorithm on real data shows improvements over existing approaches.

Keywords

Cite

@article{arxiv.1804.05436,
  title  = {Hidden Hamiltonian Cycle Recovery via Linear Programming},
  author = {Vivek Bagaria and Jian Ding and David Tse and Yihong Wu and Jiaming Xu},
  journal= {arXiv preprint arXiv:1804.05436},
  year   = {2018}
}
R2 v1 2026-06-23T01:24:14.496Z