The Computational Hardness of Counting in Two-Spin Models on d-Regular Graphs

The class of two-spin systems contains several important models, including random independent sets and the Ising model of statistical physics. We show that for both the hard-core (independent set) model and the anti-ferromagnetic Ising model with arbitrary external field, it is NP-hard to approximat...

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Bibliographic Details
Main Authors: Sly, A., Sun, N.
Format: Conference Proceeding
Language:English
Subjects:
Approximation methods
Bethe free energy
Bipartite graph
Computational modeling
Convergence
hard-core model
independent set
Ising model
Physics
Predictive models
spin system
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Summary:The class of two-spin systems contains several important models, including random independent sets and the Ising model of statistical physics. We show that for both the hard-core (independent set) model and the anti-ferromagnetic Ising model with arbitrary external field, it is NP-hard to approximate the partition function or approximately sample from the model on regular graphs when the model has non-uniqueness on the corresponding regular tree. Together with results of Jerrum -- Sinclair, Weitz, and Sinclair -- Srivastava -- Thurley giving FPRAS's for all other two-spin systems except at the uniqueness threshold, this gives an almost complete classification of the computational complexity of two-spin systems on bounded-degree graphs. Our proof establishes that the normalized log-partition function of any two-spin system on bipartite locally tree-like graphs converges to a limiting ``free energy density'' which coincides with the (non-rigorous) Be the prediction of statistical physics. We use this result to characterize the local structure of two-spin systems on locally tree-like bipartite expander graphs, which then become the basic gadgets in a randomized reduction to approximate MAX-CUT. Our approach is novel in that it makes no use of the second moment method employed in previous works on these questions.
ISSN:0272-5428
DOI:10.1109/FOCS.2012.56