Scenario Cluster Lagrangian Decomposition in two stage stochastic mixed 0-1 optimization
Fecha
2012Autor
Escudero Bueno, Laureano F.
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In this paper we introduce four scenario Cluster based Lagrangian Decomposition (CLD) procedures for obtaining strong lower bounds to the
(optimal) solution value of two-stage stochastic mixed 0-1 problems. At each iteration of the Lagrangian based procedures, the traditional aim
consists of obtaining the solution value of the corresponding Lagrangian dual via solving scenario submodels once the
nonanticipativity constraints have been dualized. Instead of considering a splitting variable representation over the set of scenarios, we propose to decompose the model into a
set of scenario clusters. We compare the computational performance of
the four Lagrange multiplier updating procedures, namely
the Subgradient Method, the Volume Algorithm, the Progressive Hedging
Algorithm and the Dynamic Constrained Cutting Plane scheme
for different numbers
of scenario clusters and different dimensions of the original
problem. Our computational experience shows that
the CLD bound and its computational effort depend on the number of
scenario clusters to consider. In any case, our results show that the CLD procedures outperform the traditional LD scheme for single
scenarios both in the quality of the bounds and computational effort. All the procedures have been implemented in a C++ experimental
code. A broad computational experience is reported on a test of
randomly generated instances by using the MIP solvers COIN-OR and CPLEX for the auxiliary mixed 0-1
cluster submodels, this last solver within
the open source engine COIN-OR. We also give computational evidence of
the model tightening effect that the preprocessing techniques, cut
generation and appending and parallel computing tools have in
stochastic integer optimization. Finally, we have observed that the
plain use of both solvers does not provide the optimal solution of
the instances included in the testbed with which we have experimented but
for two toy instances in affordable elapsed time. On the other hand the proposed
procedures provide strong lower bounds (or the same solution
value) in a considerably shorter elapsed time for the quasi-optimal
solution obtained by other means for the original stochastic problem.