Please use this identifier to cite or link to this item: https://repository.iimb.ac.in/handle/2074/11290
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dc.contributor.authorFrangioni, Antonio
dc.contributor.authorGendron, Bernard
dc.contributor.authorGorgone, Enrico
dc.date.accessioned2020-04-02T13:02:42Z-
dc.date.available2020-04-02T13:02:42Z-
dc.date.issued2017
dc.identifier.issn1867-2949
dc.identifier.urihttps://repository.iimb.ac.in/handle/2074/11290-
dc.description.abstractSubgradient methods (SM) have long been the preferred way to solve the large-scale Nondifferentiable Optimization problems arising from the solution of Lagrangian Duals (LD) of Integer Programs (IP). Although other methods can have better convergence rate in practice, SM have certain advantages that may make them competitive under the right conditions. Furthermore, SM have significantly progressed in recent years, and new versions have been proposed with better theoretical and practical performances in some applications. We computationally evaluate a large class of SM in order to assess if these improvements carry over to the IP setting. For this we build a unified scheme that covers many of the SM proposed in the literature, comprised some often overlooked features like projection and dynamic generation of variables. We fine-tune the many algorithmic parameters of the resulting large class of SM, and we test them on two different LDs of the Fixed-Charge Multicommodity Capacitated Network Design problem, in order to assess the impact of the characteristics of the problem on the optimal algorithmic choices. Our results show that, if extensive tuning is performed, SM can be competitive with more sophisticated approaches when the tolerance required for solution is not too tight, which is the case when solving LDs of IPs.
dc.publisherSpringer Verlag
dc.subjectComputational Analysis
dc.subjectLagrangian Relaxation
dc.subjectMulticommodity Network Design
dc.subjectNondifferentiable Optimization
dc.subjectSubgradient Methods
dc.titleOn the computational efficiency of subgradient methods: a case study with lagrangian bounds
dc.typeJournal Article
dc.identifier.doi10.1007/S12532-017-0120-7
dc.pages573-604p.
dc.vol.noVol.9-
dc.issue.noIss.4-
dc.journal.nameMathematical Programming Computation
Appears in Collections:2010-2019
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