Work place: Lviv Polytechnic National University, Lviv, Ukraine
E-mail: bohdankuz@gmail.com
Website:
Research Interests: Data Structures and Algorithms, Analysis of Algorithms, Combinatorial Optimization
Biography
Bohdan Kuz. Graduated from the Lviv Polytechnic National University in 2010 with master degree in Computer Science. During 2010-2013 – Ph.D. study in the Lviv Polytechnic National University in the area of mathematics and software for parallelization of large-scale TSP. In 2012, he had scholarship at the Bordeaux University (supervisor Dr. R. Dupas). Currently works for an IT company. Major fields of scientific research: software technologies, algorithms, combinatorial optimization. Has 12 scientific publications.
By Roman Bazylevych Bohdan Kuz Roman Kutelmakh Remy Dupas Bhanu Prasad Yll Haxhimusa Lubov Bazylevych
DOI: https://doi.org/10.5815/ijitcs.2016.05.01, Pub. Date: 8 May 2016
A parallel approach for solving a large-scale Traveling Salesman Problem (TSP) is presented. The problem is solved in four stages by using the following sequence of procedures: decomposing the input set of points into two or more clusters, solving the TSP for each of these clusters to generate partial solutions, merging the partial solutions to create a complete initial solution M0, and finally optimizing this solution. Lin-Kernighan-Helsgaun (LKH) algorithm is used to generate the partial solutions. The main goal of this research is to achieve speedup and good quality solutions by using parallel calculations. A clustering algorithm produces a set of small TSP problems that can be executed in parallel to generate partial solutions. Such solutions are merged to form a solution, M0, by applying the "Ring" method. A few optimization algorithms were proposed to improve the quality of M0 to generate a final solution Mf. The loss of quality of the solution by using the developed approach is negligible when compared to the existing best-known solutions but there is a significant improvement in the runtime with the developed approach. The minimum number of processors that are required to achieve the maximum speedup is equal to the number of clusters that are created.
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