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This paper describes the influence of the varying computation precision when performing calculations using the optimizing algorithms. A comparative analysis of the computation speed and obtained result accuracy of the Rastrigin’s direct cone method with adapting of the step length and the angle of the cone's disclosure for varying precision was performed. It is shown that the speed of the optimization algorithm practically does not depend on used computation precision. The difference is observed only in accuracy of the obtained results. The investigation of optimizing algorithms behavior under the presence of noise, in particular due to rounding errors was conducted. It is shown that the optimizing algorithm under research becomes unsuitable after some noise level. Characteristics of the optimization algorithm during calculations with a single precision proved to be better then the characteristics of the algorithm when performing calculations with double precision. The analysis of possibilities of the effective graphics processors (GPU) application in order to conduct optimization was carried out. In particular, the difference in the speed of the GPU when performing calculations with a single and double precision was considered. To ensure the efficiency of calculations based on optimization algorithms, it is recommended to carry out calculations with the use of single precision, and increase the calculation precision in case of impossibility to achieve the desired accuracy of the result. There is considering the significantly higher performance of graphics processors when doing calculations with a single precision in comparison with calculations with double precision it is expedient to use a single calculation precision when graphic processors are used to solve considered problem. Double precision can be used if it is difficult to get sufficiently correct solution by single precision calculations. The results of numerical experiments confirm that the use of lower precision to perform optimization for macromodels creation has a slight influence on the speed of achieving of predetermined optimization accuracy.
Słowa kluczowe
Czasopismo
Rocznik
Tom
Strony
121--126
Opis fizyczny
Bibliogr. 17 poz., wykr., wz.
Twórcy
autor
- Łódź University of Technology
autor
- Łódź University of Technology
autor
- Lviv Polytechnic National University
Bibliografia
- 1. Stakhiv P., Kozak Yu., Hoholyuk O. 2011. Construction of macromodels of nonlinear dynamic systems using optimization Computational Problems of Electrical Engineering. – . № 1., 95 – 102.
- 2. Stakhiv P., Kozak Yu., Selepyna Yo. 2010. Improvement of optimization algorithm for identification of the macromodel parameters of electromechanical systems. Visnyk of Lviv Polytechnic National University “Electric power engineering and electromechanical systems” . № 666. 98 – 102. (in Ukrainian)
- 3. Stakhiv P., Kozak Yu., Hoholyuk O. 2014. Disctrete modeling in electric engineering and relative fields. Lviv: Publishing House of Lviv Polytechnic National University , 260. (in Ukrainian)
- 4. Salinelli E., Tomarelli F. 2014 Discrete Dynamical Models / Springer International Publishing Switzerland
- 5. Rosenbrock, H. H. 1960. An automatic method for finding the greatest or least value of a function", The Computer Journal 3: 175–184.
- 6. "NVIDIA Kepler GK110 Architecture Whitepaper" (PDF). Retrieved 2015-09-19.
- 7. Bukashkin S. A. 1989. Numerical methods of optimal synthesis of linear and nonlinear recurrent electronic circuits. DSc thesis, 480. (in Russian).
- 8. Boreskov A.V. 2012. Parallel calculations using GPU. Arcitecture and program model. Moscow: Publishing House of the Moscow University, 336. (in Russian).
- 9. Ashlock, D. 2006. Evolutionary Computation for Modelling and Optimization. – Springer, 571.
- 10. Munshi A., Gaster B. R., Mattson, T. G. Fung J., Ginsburg D. 2011 OpenCL Programming Guide. Addison-Wesley Professional, 648.
- 11. Stakhiv P., Kozak Yu. 2011 Discrete dynamic macromodels and their usage in electrical engineering International Journal of Computing. Vol 10, 278 – 284.
- 12. Stakhiv P. Strubytska I., Kozak Yu., 2012 Parallelization of calculations using GPU in optimization approach for macromodels construction. Przeglad Electrotechniczny. Vol 3a., 7 – 9.
- 13. “NVIDIA GeForce GTX 980 Whitepaper" (PDF) http://international.download.nvidia.com/geforcecom/international/pdfs/GeForce_GTX_980_Whitepaper_FINAL.PDF
- 14. Bertsekas, Dimitri P., 1999. Nonlinear Programing (Second ed.). Cambridge, MA.: Athena Scientific. ISBN 1-886529-00-0.
- 15. Ruszczyński, Andrzej, 2006. Nonlinear Optimization. Princeton, NJ: Princeton University Press. pp. xii+454. ISBN 978-0691119151. MR 2199043.
- 16. Shakhovska, N., Medykovsky, M., Stakhiv, P. 2013. Application of algorithms of classification for uncertainty reduction. Przeglad Elektrotechniczny, 89(4), 284-286.
- 17. Bobalo, Y., Stakhiv, P., Shakhovska, N. 2015. Features of an eLearning software for teaching and self-studying of electrical engineering. In Computational Problems of Electrical Engineering (CPEE), 2015 16th International Conference on (pp. 7-9). IEEE.
Uwagi
PL
Opracowanie ze środków MNiSW w ramach umowy 812/P-DUN/2016 na działalność upowszechniającą naukę
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-a59b8f6d-d5dd-449a-9c54-4b5c3e2bdc68