Abstract
This paper presents mathematical software designed to test and adjust the technological process of induction soldering of waveguide paths. The development of the technological process in the form of full-scale experiments is an expensive and time-consuming process. The use of mathematical software will reduce the labor intensity and cost of development of the technological process due to the fact that the development of the field experiments will be made on the basis of technological parameters selected on the basis of model data. The mathematical software is a complex of mathematical models of both individual elements and the entire assembly of the waveguide path as a whole. The software is the implementation of these mathematical models to test and configure the induction soldering process. Visual Studio Community 2019 is used as a development tool. The license conditions allow using this tool for academic research purposes. The software is developed within the framework of the object-oriented approach. Using this software will simplify and reduce the cost of testing and setting up the technological process of induction soldering of waveguide paths.
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This research was financially supported by Reshetnev Siberian State University of Science and Technology project “Mathematical software of the induction soldering of spacecraft’s waveguide paths”.
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Milov, A., Tynchenko, V., Petrenko, V., Kukartsev, V. (2020). Mathematical Software for Testing and Setting up the Induction Soldering Process. In: Jordan, V., Filimonov, N., Tarasov, I., Faerman, V. (eds) High-Performance Computing Systems and Technologies in Scientific Research, Automation of Control and Production. HPCST 2020. Communications in Computer and Information Science, vol 1304. Springer, Cham. https://doi.org/10.1007/978-3-030-66895-2_8
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