Improved Approximation Algorithms for Bounded-Degree Local Hamiltonians

AbstractWe study the connection between the correlation decay property (more precisely, strong spatial mixing) and the zero-freeness of the partition function of 2-spin systems on graphs of bounded degree. We show that for 2-spin systems on an entire family of graphs of a given bounded degree, the contraction property that ensures correlation decay exists for certain real parameters implies the zero-freeness of the partition function and the existence of correlation decay for some corresponding complex neighborhoods. Based on this connection, we are able to extend any real parameter of which the 2-spin system on graphs of bounded degree exhibits correlation decay to its complex neighborhood where the partition function is zero-free and correlation decay still exists. We give new zero-free regions in which the edge interaction parameters and the uniform external field are all complex-valued, and we show the existence of correlation decay for such complex regions. As a consequence, we obtain approximation algorithms for computing the partition function of 2-spin systems on graphs of bounded degree for these complex parameter settings.

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Approximation Algorithms for Bounded Degree Phylogenetic Roots

Algorithmica ◽

10.1007/s00453-007-9072-z ◽

2007 ◽

Vol 51 (1) ◽

pp. 1-23 ◽

Cited By ~ 2

Author(s):

Zhi-Zhong Chen

Keyword(s):

Approximation Algorithms ◽

Bounded Degree

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Cycle transversals in bounded degree graphs

Discrete Mathematics & Theoretical Computer Science ◽

10.46298/dmtcs.533 ◽

2011 ◽

Vol Vol. 13 no. 1 (Graph and Algorithms) ◽

Author(s):

Marina Groshaus ◽

Pavol Hell ◽

Sulamita Klein ◽

Loana Tito Nogueira ◽

Fábio Protti

Keyword(s):

Approximation Algorithms ◽

Polynomial Time ◽

Maximum Degree ◽

Decomposition Theorem ◽

Np Hard ◽

Input Graph ◽

Bounded Degree ◽

Time Approximation ◽

International Audience ◽

Bounded Degree Graphs

Graphs and Algorithms International audience In this work we investigate the algorithmic complexity of computing a minimum C(k)-transversal, i.e., a subset of vertices that intersects all the chordless cycles with k vertices of the input graph, for a fixed k \textgreater= 3. For graphs of maximum degree at most three, we prove that this problem is polynomial-time solvable when k \textless= 4, and NP-hard otherwise. For graphs of maximum degree at most four, we prove that this problem is NP-hard for any fixed k \textgreater= 3. We also discuss polynomial-time approximation algorithms for computing C(3)-transversals in graphs of maximum degree at most four, based on a new decomposition theorem for such graphs that leads to useful reduction rules.

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Classical and quantum bounded depth approximation algorithms

Quantum Information and Computation ◽

10.26421/qic19.13-14-3 ◽

2019 ◽

Vol 19 (13&14) ◽

pp. 1116-1140

Author(s):

Matthew B. Hastings

Keyword(s):

Approximation Algorithms ◽

Strong Evidence ◽

Optimization Algorithms ◽

Fixed Number ◽

Single Step ◽

Literature Cite ◽

Bounded Degree ◽

Approximate Optimization ◽

Bounded Degree Graphs ◽

Classical Optimization

We consider some classical and quantum approximate optimization algorithms with bounded depth. First, we define a class of "local" classical optimization algorithms and show that a single step version of these algorithms can achieve the same performance as the single step QAOA on MAX-3-LIN-2. Second, we show that this class of classical algorithms generalizes a class previously considered in the literature\cite{hirvonen2014large}, and also that a single step of the classical algorithm will outperform the single-step QAOA on all triangle-free MAX-CUT instances. In fact, for all but 4 choices of degree, existing single-step classical algorithms already outperform the QAOA on these graphs, while for the remaining 4 choices we show that the generalization here outperforms it. Finally, we consider the QAOA and provide strong evidence that, for any fixed number of steps, its performance on MAX-3-LIN-2 on bounded degree graphs cannot achieve the same scaling as can be done by a class of ``global" classical algorithms. These results suggest that such local classical algorithms are likely to be at least as promising as the QAOA for approximate optimization.

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