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Combinatorial optimization and the mean field model. Johan Wästlund Chalmers University of Technology Sweden. Random instances of optimization problems. Random instances of optimization problems. Random instances of optimization problems.
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Combinatorial optimization and the mean field model Johan Wästlund Chalmers University of Technology Sweden
Random instances of optimization problems • Typical distance between nearby points is of order n-1/2
Random instances of optimization problems • A tour consists of n links, therefore we expect the total length of the minimum tour to scale like n1/2 • Beardwood-Halton-Hammersley (1959):
Mean field model of distance • Distances Xij chosen as i.i.d. variables • Given n and the distribution of distances, study the random variable Ln • If the distribution models distances in d dimensions, we expect Ln to scale like n1-1/d • In particular, pseudo-dimension 1 means Ln is asymptotically independent of n
Mean field model of distance • The edges of a complete graph on n vertices are given i. i. d. nonnegative costs • Exponential(1) distribution.
Mean field model of distance • We are interested in the cost of the minimum matching, minimum traveling salesman tour etc, for large n.
Mean field model of distance Convergence in probability to a constant?
Matching • Set of edges that gives a pairing of all points
Statistical Physics / C-S • Feasible solution • Cost of solution • Cost of minimal solution • Artificial parameter T • Gibbs measure • n→∞ • Spin configuration • Hamiltonian • Ground state energy • Temperature • Gibbs measure • Thermodynamic limit
Statistical physics • Replica-cavity method of statistical mechanics has given spectacular predictions for random optimization problems • M. Mézard, G. Parisi 1980’s • Limit of p2/12 for minimum matching on the complete graph (Aldous 2000) • Limit 2.0415… for the TSP (Wästlund 2006)
A. Frieze (2004): “Up to now there has been almost no progress analysing this random model of the travelling salesman problem.” • N. J. Cerf et al (1997): “Researchers outside physics remain largely unaware of the analytical progress made on the random link TSP.”
Non-rigorous derivation of the p2/12 limit • Matching problem on Kn for large n. • In principle, this requires even n, but we shall consider a relaxation • Let the edges be exponential of mean n, so that the sequence of ordered edge costs from a given vertex is approximately a Poisson process of rate 1.
Non-rigorous derivation of the p2/12 limit • The total cost of the minimum matching is of order n. • Introduce a punishment c>0 for not using a particular vertex. • This makes the problem well-defined also for odd n. • For fixed c, let n tend to infinity. • As c tends to infinity, we expect to recover the behavior of the original problem.
Non-rigorous derivation of the p2/12 limit • For large n, suppose that the problem behaves in the same way for n-1 vertices. • Choose an arbitrary vertex to be the root • What does the graph look like locally around the root? • When only edges of cost <2c are considered, the graph becomes locally tree-like
Non-rigorous derivation of the p2/12 limit • Non-rigorous replica-cavity method • Aldous derived equivalent equations with the Poisson-Weighted Infinite Tree (PWIT)
Non-rigorous derivation of the p2/12 limit • Let X be the difference in cost between the original problem and that with the root removed. • If the root is not matched, then X = c. Otherwise X = xi – Xi, where Xi is distributed like X, and xi is the cost of the i:th edge from the root. • The Xi’s are assumed to be independent.
Non-rigorous derivation of the p2/12 limit It remains to do some calculations. We have where Xi is distributed like X
X Non-rigorous derivation of the p2/12 limit • Let -u
Non-rigorous derivation of the p2/12 limit • Then if u>-c,
Non-rigorous derivation of the p2/12 limit Hence is constant
Non-rigorous derivation of the p2/12 limit f(-u) • The constant depends on c and holds when –c<u<c f(u)
Non-rigorous derivation of the p2/12 limit • From definition, exp(-f(c)) = P(X=c) = proportion of vertices that are not matched, and exp(-f(-c)) = exp(0) = 1 • e-f(u) + e-f(-u) = 2 – proportion of vertices that are matched = 1 when c = infinity.
Non-rigorous derivation of the p2/12 limit • What about the cost of the minimum matching?
Non-rigorous derivation of the p2/12 limit • Hence J = area under the curve when f(u) is plotted against f(-u)! • Expected cost = n/2 times this area • In the original setting = ½ times the area = p2/12.
The equation has the explicit solution • This gives the cost
The exponential bipartite assignment problem • Exact formula conjectured by Parisi (1998) • Suggests proof by induction • Researchers in discrete math, combinatorics and graph theory became interested • Generalizations…
Generalizations • by Coppersmith & Sorkin to incomplete matchings • Remarkable paper by M. Buck, C. Chan & D. Robbins (2000) • Introduces weighted vertices • Extremely close to proving Parisi’s conjecture!
Weighted assignment problems • Weights 1,…,m, 1,…, n on vertices • Edge cost exponential of rate ij • Conjectured formula for the expected cost of minimum assignment • Formula for the probability that a vertex participates in solution (trivial for less general setting!)
a3 a1 a2 The Buck-Chan-Robbins urn process • Balls are drawn with probabilities proportional to weight
Proofs of the conjectures • Two independent proofs of the Parisi and Coppersmith-Sorkin conjectures in 2003 (Nair, Prabhakar, Sharma and Linusson, Wästlund)
Rigorous method • Relax by introducing an extra vertex • Let the weight of the extra vertex go to zero • Example: Assignment problem with 1=…=m=1, 1=…=n=1, and m+1 = • p = P(extra vertex participates) • p/n = P(edge (m+1,n) participates)
Rigorous method • p/n = P(edge (m+1,n) participates) • When →0, this is • Hence • By Buck-Chan-Robbins urn theorem,
Rigorous method • Hence • Inductively this establishes the Coppersmith-Sorkin formula
Rigorous results • Much simpler proofs of Parisi, Coppersmith-Sorkin, Buck-Chan-Robbins formulas • Exact results for higher moments • Exact results and limits for optimization problems on the complete graph
The 2-dimensional urn process • 2-dimensional time until k balls have been drawn
Limit shape as n→∞ • Matching: • TSP/2-factor:
Mean field TSP • If the edge costs are i.i.d and satisfy P(l<t)/t→1 as t→0 (pseudodimension 1), then as n →∞,
It follows that is constant, and = 1 by boundary conditions • Replica-cavity prediction agrees with the rigorous result (Parisi 2006)
Future work • Explain why the cavity method gives the same equation as the limit shape in the urn process • Reprove results of one method with the other • Find the variance with the replica method • Find rigorously the distribution of edge costs participating in the solution (there is an exact conjecture)