RESEARCH, AND MODELING IN THE SUBJECT AREA OF COMPUTER TECHNOLOGIES FOR THE THREE-DIMENSIONAL PRINTING IN THE CONTEXT OF PERFECTION FOR COMPUTER SYSTEMS OF THE INFORMATION SUPPORT IN THE INDEPENDENT WORK ON ACQUISITION OF COMPETENCE IN THIS AREA
DOI:
https://doi.org/10.32782/2618-0340-2019-3-11Keywords:
computer systems, computer technologies, three-dimensional printing, information support, the subject area, competence, independent work, research, modelingAbstract
The advantages, problematic aspects, and a number of key features of the semantics for a highly relevant, practically significant and dynamically developing subject area of computer technology for three-dimensional printing, with an emphasis on the advanced technologies and applied applications that most actively stimulate the development of the three-dimensional printing, are explored. The main sources, and the most appropriate for the application possibilities in solving of the problem on improving for computer systems providing information support for the processes of self-mastering in the field of threedimensional printing, with the acquisition of appropriate competencies are analyzed. According to the results of the analysis in the semantics of the subject area, the expediency on the formation of a knowledge base regarding developers, application areas, and recommendations rules regarding the optimal choice of three-dimensional printing technologies is substantiated. A number of new approaches to building models of knowledge bases for expert subsystems of computer systems on information support for independent work on obtaining competencies in the field of three-dimensional printing have been formed. In particular, for describing the fundamentally factual information of the knowledge base regarding three-dimensional printing technologies, the economic development of threedimensional printing application areas, the display of numerical forecast indicators of the highest costs for equipment for the three-dimensional printing industry, respectively, specific directions of expenses and for certain application areas, formats of the predicates constructions to describe the relevant database of facts are represented. For the purpose of greater clarity, examples of concretization of predicates are given. The research results are applied to improve the educational process in special disciplines for the Department of Information Technology of the Faculty of Cybernetics and Systems Engineering at Kherson National Technical University.
References
Luneva D. A., Kozhevnikova E. O., Kaloshina S. V. Application and prospects of 3D printing in construction activities. Bulletin of Perm National Research Polytechnic University. Construction and Architecture. 2017. Vol. 8, № 1. P. 90−101. DOI: 10.15593/2224-9826/2017.1.0 [in Russian].
Moorefield-Lang H. M. Makers in the library: case studies of 3D printers and maker spaces in library settings. Library Hi Tech. 2014. Vol. 32, Issue 4. P. 583−593. DOI: 10.1108/LHT- 06-2014-0056.
Pryor S. Implementing a 3D Printing Service in an Academic Library. Journal of Library Administration. 2014. Vol. 54, Issue 1. P. 1−10. DOI: 10.1080/01930826.2014.893110.
Solomon J. Numerical algorithms: methods for computer vision, machine learning, and graphics: textbook. USA: CRC Press (AK Peters, Ltd.), 2015. 400 p.
Stecca G. (Eds.) Operations research applications. Rome, Italy: AIRO (Associazone Italiana di Ricerca Operativa), 2017. 123 p.
Yang X. Optimization techniques and applications with examples. USA, UK: WILEY, 2018. 384 p.
Ziegelmann J. P., Lippke S. Use of Selection, Optimization, and Compensation strategies in health self-regulation: Interplay with resources and successful development. Journal of Aging and Health. 2007. № 19. P. 500−518.
Ногин, В. Д. Принятие решений в многокритериальной среде: количественный подход. Москва: Физматлит, 2005.176 с.
Подиновский, В. В., Ногин, В. Д. Парето-оптимальные решения многокритериальных задач. М.: Физматлит, 2007. 256 с.
