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Tutorial
on Modern Linkage Learning Techniques in Combinatorial Optimization |
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Organizers |
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Michal Witold
Przewozniczek (main organizer) |
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Department
of Computer Science, Wroclaw University of Science and Technology, Poland |
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Dr.
Michal Witold Przewozniczek
received the M.Sc. and Ph.D. degrees in computer science in 2003 and 2012, respectively,
from Wroclaw University of Science and Technology (WUST), Poland. He is an
Assistant Professor with the Wroclaw University of Science and Technology in
the Department of Computational Intelligence. In 2019, while associated with
WUST, he also worked as a researcher at the Department of Computer Science,
The University of York, England. Michal’s research concentrates on the
application of evolutionary algorithms to practical problems. To obtain this
objective, he investigates the linkage learning techniques, multi-population
approaches, dynamic management of subpopulations, and others. This experience
helped in solving hard multi-objective industrial problems as a team member
at The University of York. Michal is also a co-owner of a software company.
He invented and implemented in the industry many prototype systems. |
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Marcin
Michal Komarnicki (co-organizer) |
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Department
of Computer Science, Wroclaw University of Science and Technology, Poland |
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Marcin Michal Komarnicki
received the B.S. and M.S. degrees in computer science from Wroclaw
University of Science and Technology, Poland, in 2013 and 2014, respectively,
where he is currently pursuing the Ph.D. degree. His current research
interests include large-scale optimization, linkage learning techniques, and
multi-population approaches. One of the main directions of Marcin’s research
is proposing more effective linkage learning techniques for continuous search
spaces. Marcin is also a professional software developer.
His professional work includes the applications of evolutionary computation
into the production process planning in industry. |
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The
most important research achievements of tutorial organizers that concern
linkage learning and were published in 2020/21 are
as follows. |
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Journal
papers |
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1. M.W. Przewozniczek, M. M. Komarnicki,
“Empirical linkage learning,” IEEE
Transactions on Evolutionary Computation,
vol. 24, no. 6, pp. 1097-1111, 2020. 2. M. W. Przewozniczek,
P. Dziurzanski, S. Zhao, L. S. Indrusiak,
“Multi-Objective Parameter-less Population Pyramid for Solving Industrial
Process Planning Problems,” Swarm and
Evolutionary Computation, 2021 (in press) 3. M. W. Przewoźniczek,
“Subpopulation initialization driven by linkage learning for dealing with the
Long-Way-To-Stuck effect,” Information
Sciences, vol. 521, pp. 62-80, 2020. 4. M. W. Przewozniczek,
R. Datta, K. Walkowiak,
M. Komarnicki, “Splitting the fitness and penalty
factor for temporal diversity increase in practical problem solving,” Expert Systems With Applications, vol.
145, pp.1-11, 2020. 5.
M.W. Przewozniczek, R, Goścień,
P. Lechowicz, K. Walkowiak,
"Metaheuristic Algorithms with Solution Encoding Mixing for Effective
Optimization of SDM Optical Networks," Engineering Applications of Artificial Intelligence, 2020 (in
press). |
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Conference
papers |
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1. M.W. Przewozniczek,
M. M. Komarnicki, B. Frej,
"Direct linkage discovery with empirical linkage learning," in Proceedings of the 2021 Genetic and
Evolutionary Computation Conference (GECCO ’21). ACM, 2021 (in press). 2. M. W. Przewozniczek,
M. M. Komarnicki, "Fitness caching - from a
minor mechanism to major consequences in modern evolutionary
computation," in Proceedings of
the IEEE Congress on Evolutionary Computation (CEC), 2021 (in press). 3. M. W. Przewozniczek,
B. Frej, M. M. Komarnicki,
“On measuring and improving the quality of linkage learning in modern
evolutionary algorithms applied to solve partially additively separable
problems,” in Proceedings of the 2020
Genetic and Evolutionary Computation Conference (GECCO ’20). ACM, pp.
742–750, 2020. 4. M. M. Komarnicki,
M. W. Przewozniczek, T. Durda,
”Comparative Mixing for DSMGA-II,” in Proceedings
of the 2020 Genetic and Evolutionary Computation Conference (GECCO ’20),
ACM, pp. 708–716, 2020. 5. S.
Wozniak, M. W. Przewozniczek, and M. M. Komarnicki, ”Parameter-less
population pyramid for permutation-based problems,” in Proceedings of the Parallel Problem Solving from Nature (PPSN XVI),
pp. 418-430, 2020. |
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