91 research outputs found
#BIS-hardness for 2-spin systems on bipartite bounded degree graphs in the tree non-uniqueness region
Counting independent sets on bipartite graphs (#BIS) is considered a
canonical counting problem of intermediate approximation complexity. It is
conjectured that #BIS neither has an FPRAS nor is as hard as #SAT to
approximate. We study #BIS in the general framework of two-state spin systems
on bipartite graphs. We define two notions, nearly-independent phase-correlated
spins and unary symmetry breaking. We prove that it is #BIS-hard to approximate
the partition function of any 2-spin system on bipartite graphs supporting
these two notions. As a consequence, we classify the complexity of
approximating the partition function of antiferromagnetic 2-spin systems on
bounded-degree bipartite graphs
Ferromagnetic Potts Model: Refined #BIS-hardness and Related Results
Recent results establish for 2-spin antiferromagnetic systems that the
computational complexity of approximating the partition function on graphs of
maximum degree D undergoes a phase transition that coincides with the
uniqueness phase transition on the infinite D-regular tree. For the
ferromagnetic Potts model we investigate whether analogous hardness results
hold. Goldberg and Jerrum showed that approximating the partition function of
the ferromagnetic Potts model is at least as hard as approximating the number
of independent sets in bipartite graphs (#BIS-hardness). We improve this
hardness result by establishing it for bipartite graphs of maximum degree D. We
first present a detailed picture for the phase diagram for the infinite
D-regular tree, giving a refined picture of its first-order phase transition
and establishing the critical temperature for the coexistence of the disordered
and ordered phases. We then prove for all temperatures below this critical
temperature that it is #BIS-hard to approximate the partition function on
bipartite graphs of maximum degree D. As a corollary, it is #BIS-hard to
approximate the number of k-colorings on bipartite graphs of maximum degree D
when k <= D/(2 ln D).
The #BIS-hardness result for the ferromagnetic Potts model uses random
bipartite regular graphs as a gadget in the reduction. The analysis of these
random graphs relies on recent connections between the maxima of the
expectation of their partition function, attractive fixpoints of the associated
tree recursions, and induced matrix norms. We extend these connections to
random regular graphs for all ferromagnetic models and establish the Bethe
prediction for every ferromagnetic spin system on random regular graphs. We
also prove for the ferromagnetic Potts model that the Swendsen-Wang algorithm
is torpidly mixing on random D-regular graphs at the critical temperature for
large q.Comment: To appear in SIAM J. Computin
Ferromagnetic Potts Model: Refined #BIS-hardness and Related Results
Recent results establish for the hard-core model (and more generally for 2-spin antiferromagnetic systems) that the computational complexity of approximating the partition function on graphs of maximum degree D undergoes a phase transition that coincides with the uniqueness/non-uniqueness phase transition on the infinite D-regular tree. For the ferromagnetic Potts model we investigate whether analogous hardness results hold. Goldberg and Jerrum showed that approximating the partition function of the ferromagnetic Potts model is at least as hard as approximating the number of independent sets in bipartite graphs, so-called #BIS-hardness. We improve this hardness result by establishing it for bipartite graphs of maximum degree D. To this end, we first present a detailed picture for the phase diagram for the infinite D-regular tree, giving a refined picture of its first-order phase transition and establishing the critical temperature for the coexistence of the disordered and ordered phases. We then prove for all temperatures below this critical temperature (corresponding to the region where the ordered phase "dominates") that it is #BIS-hard to approximate the partition function on bipartite graphs of maximum degree D.
The #BIS-hardness result uses random bipartite regular graphs as a gadget in the reduction. The analysis of these random graphs relies on recent results establishing connections between the maxima of the expectation of their partition function, attractive fixpoints of the associated tree recursions, and induced matrix norms. In this paper we extend these connections to random regular graphs for all ferromagnetic models. Using these connections, we establish the Bethe prediction for every ferromagnetic spin system on random regular graphs, which says roughly that the expectation of the log of the partition function Z is the same as the log of the expectation of Z. As a further consequence of our results, we prove for the ferromagnetic Potts model that the Swendsen-Wang algorithm is torpidly mixing (i.e., exponentially slow convergence to its stationary distribution) on random D-regular graphs at the critical temperature for sufficiently large q
Counting Independent Sets and Colorings on Random Regular Bipartite Graphs
We give a fully polynomial-time approximation scheme (FPTAS) to count the number of independent sets on almost every Delta-regular bipartite graph if Delta >= 53. In the weighted case, for all sufficiently large integers Delta and weight parameters lambda = Omega~ (1/(Delta)), we also obtain an FPTAS on almost every Delta-regular bipartite graph. Our technique is based on the recent work of Jenssen, Keevash and Perkins (SODA, 2019) and we also apply it to confirm an open question raised there: For all q >= 3 and sufficiently large integers Delta=Delta(q), there is an FPTAS to count the number of q-colorings on almost every Delta-regular bipartite graph
Inapproximability of the Partition Function for the Antiferromagnetic Ising and Hard-Core Models
Recent inapproximability results of Sly (2010), together with an
approximation algorithm presented by Weitz (2006) establish a beautiful picture
for the computational complexity of approximating the partition function of the
hard-core model. Let denote the critical activity for the
hard-model on the infinite -regular tree. Weitz presented an FPTAS for
the partition function when for graphs with
constant maximum degree . In contrast, Sly showed that for all
, there exists such that (unless RP=NP) there
is no FPRAS for approximating the partition function on graphs of maximum
degree for activities satisfying
.
We prove that a similar phenomenon holds for the antiferromagnetic Ising
model. Recent results of Li et al. and Sinclair et al. extend Weitz's approach
to any 2-spin model, which includes the antiferromagnetic Ising model, to yield
an FPTAS for the partition function for all graphs of constant maximum degree
when the parameters of the model lie in the uniqueness regime of the
infinite tree . We prove the complementary result that for the
antiferrogmanetic Ising model without external field that, unless RP=NP, for
all , there is no FPRAS for approximating the partition function
on graphs of maximum degree when the inverse temperature lies in the
non-uniqueness regime of the infinite tree . Our results extend to a
region of the parameter space for general 2-spin models. Our proof works by
relating certain second moment calculations for random -regular
bipartite graphs to the tree recursions used to establish the critical points
on the infinite tree.Comment: Journal version (no changes
FPTAS for #BIS with Degree Bounds on One Side
Counting the number of independent sets for a bipartite graph (#BIS) plays a
crucial role in the study of approximate counting. It has been conjectured that
there is no fully polynomial-time (randomized) approximation scheme
(FPTAS/FPRAS) for #BIS, and it was proved that the problem for instances with a
maximum degree of is already as hard as the general problem. In this paper,
we obtain a surprising tractability result for a family of #BIS instances. We
design a very simple deterministic fully polynomial-time approximation scheme
(FPTAS) for #BIS when the maximum degree for one side is no larger than .
There is no restriction for the degrees on the other side, which do not even
have to be bounded by a constant. Previously, FPTAS was only known for
instances with a maximum degree of for both sides.Comment: 15 pages, to appear in STOC 2015; Improved presentations from
previous version
Counting Constraint Satisfaction Problems
This chapter surveys counting Constraint Satisfaction Problems (counting CSPs, or #CSPs) and their computational complexity. It aims to provide an introduction to the main concepts and techniques, and present a representative selection of results and open problems. It does not cover holants, which are the subject of a separate chapter
Algorithms for #BIS-hard problems on expander graphs
We give an FPTAS and an efficient sampling algorithm for the high-fugacity hard-core model on bounded-degree bipartite expander graphs and the low-temperature ferromagnetic Potts model on bounded-degree expander graphs. The results apply, for example, to random (bipartite) Δ-regular graphs, for which no efficient algorithms were known for these problems (with the exception of the Ising model) in the non-uniqueness regime of the infinite Δ-regular tree
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