Dynamic Programming Optimization over Random Data: the Scaling Exponent for Near-optimal Solutions
Abstract
A very simple example of an algorithmic problem solvable by dynamic programming is to maximize, over sets A in {1,2,...,n}, the objective function |A| - \sum_i \xi_i 1(i \in A,i+1 \in A) for given \xi_i > 0. This problem, with random (\xi_i), provides a test example for studying the relationship between optimal and near-optimal solutions of combinatorial optimization problems. We show that, amongst solutions differing from the optimal solution in a small proportion \delta of places, we can find near-optimal solutions whose objective function value differs from the optimum by a factor of order \delta^2 but not smaller order. We conjecture this relationship holds widely in the context of dynamic programming over random data, and Monte Carlo simulations for the Kauffman-Levin NK model are consistent with the conjecture. This work is a technical contribution to a broad program initiated in Aldous-Percus (2003) of relating such scaling exponents to the algorithmic difficulty of optimization problems.
Cite
@article{arxiv.0710.0857,
title = {Dynamic Programming Optimization over Random Data: the Scaling Exponent for Near-optimal Solutions},
author = {David J. Aldous and Charles Bordenave and Marc Lelarge},
journal= {arXiv preprint arXiv:0710.0857},
year = {2007}
}
Comments
35 pages