Online Combinatorial Optimization with Graphical Dependencies

Most existing work in online stochastic combinatorial optimization assumes that inputs are drawn from independent distributions -- a strong assumption that often fails in practice. At the other extreme, arbitrary correlations are equivalent to worst-case inputs via Yao's minimax principle, making good algorithms often impossible. This motivates the study of intermediate models that capture mild correlations while still permitting non-trivial algorithms. In this paper, we study online combinatorial optimization under Markov Random Fields (MRFs), a well-established graphical model for structured dependencies. MRFs parameterize correlation strength via the maximum weighted degree $Δ$, smoothly interpolating between independence ($Δ= 0$) and full correlation ($Δ\to \infty$). While naïvely this yields $e^{O(Δ)}$-competitive algorithms and $Ω(Δ)$ hardness, we ask: when can we design tight $Θ(Δ)$-competitive algorithms? We present general techniques achieving $O(Δ)$-competitive algorithms for both minimization and maximization problems under MRF-distributed inputs. For minimization problems with coverage constraints (e.g., Facility Location and Steiner Tree), we reduce to the well-studied $p$-sample model. For maximization problems (e.g., matchings and combinatorial auctions with XOS buyers), we extend the "balanced prices" framework for online allocation problems to MRFs.