Context. A modern stage of powerful radio-electronic and electrotechnical systems development, with a power more than 1 MW, imposes increased requirements to their energy equipment, uninterrupted operation and power supply reliability in various operational modes. Field simulation of such systems class is based on modern numerical realization methods of boundary value problems for Helmholtz and Maxwell equations, both in single-connected and multi-connected domains. It imposes increased requirements to resources, computer hardware speed and software computing efficiency, defining the relevance of a new mathematical apparatus development or its elaboration, including combinations of analytical and approximate numerical methods.<br />Objective. The purpose of work is the elaboration a new numerical realization methods of field models taking into account AC<br />electrophysical processes with high frequency on the basis of Helmholtz equations in frequency formulations, adapted to software packages<br />use with a free license.<br />Method. A new method of frequency adaptation is elaborated, which provides systems of Helmholtz equations reduction in vector<br />magnetic potential formulations to the recurrent modified Maxwell’s equations, in analogies of DC formulation, and also provides high<br />precision and field simulation efficiency.<br />Results. The generalized spatial mathematical model of interrelated electromagnetic and electrothermal processes AC energy conversion<br />in current-conducting wires of powerful radio-electronic and electrotechnical systems is offered. This model considers operational modes, nonlinear dependences of electrophysical properties in electrotechnical materials, replacement effects and outer superficial effects, self- and mutual induction. A new method of frequency adaptation is elaborated, based on Helmholtz system of equations reduction in the vector magnetic potential formulations, in frequency domain, to the recurrent modified Maxwell’s equations, in analogies of DC formulation, and also provides high precision and field simulation efficiency. At numerical realization of frequency adaptation methods and finite elements, the number of freedom degrees decreases twice. It is caused by step-by-step solution the recurrent modified Maxwell’s equations, in analogies of DC formulations, for real and imaginary components of electric and vector magnetic potentials.<br />Conclusions. The elaborated new frequency adaptation method significantly expands possibilities of production design preparation for<br />powerful radio engineering systems. It allows using the software packages with a free license, reduces requirements to computing resources, reduces time costs and provides high precision in electromagnetic fields simulation.
Науковий журнал «Радіоелектроніка, інформатика, управління»
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Yarymbash, D. S.; Zaporozhye National Technical University, Ukraine Yarymbash, S. T.; Zaporozhye National Technical University, Ukraine Kotsur, M. I.; Zaporozhye National Technical University, Ukraine Litvinov, D. O.; Zaporozhye National Technical University, Ukraine |
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Context. A modern stage of powerful radio-electronic and electrotechnical systems development, with a power more than 1 MW, imposes increased requirements to their energy equipment, uninterrupted operation and power supply reliability in various operational modes. Field simulation of such systems class is based on modern numerical realization methods of boundary value problems for Helmholtz and Maxwell equations, both in single-connected and multi-connected domains. It imposes increased requirements to resources, computer hardware speed and software computing efficiency, defining the relevance of a new mathematical apparatus development or its elaboration, including combinations of analytical and approximate numerical methods.<br />Objective. The purpose of work is the elaboration a new numerical realization methods of field models taking into account AC<br />electrophysical processes with high frequency on the basis of Helmholtz equations in frequency formulations, adapted to software packages<br />use with a free license.<br />Method. A new method of frequency adaptation is elaborated, which provides systems of Helmholtz equations reduction in vector<br />magnetic potential formulations to the recurrent modified Maxwell’s equations, in analogies of DC formulation, and also provides high<br />precision and field simulation efficiency.<br />Results. The generalized spatial mathematical model of interrelated electromagnetic and electrothermal processes AC energy conversion<br />in current-conducting wires of powerful radio-electronic and electrotechnical systems is offered. This model considers operational modes, nonlinear dependences of electrophysical properties in electrotechnical materials, replacement effects and outer superficial effects, self- and mutual induction. A new method of frequency adaptation is elaborated, based on Helmholtz system of equations reduction in the vector magnetic potential formulations, in frequency domain, to the recurrent modified Maxwell’s equations, in analogies of DC formulation, and also provides high precision and field simulation efficiency. At numerical realization of frequency adaptation methods and finite elements, the number of freedom degrees decreases twice. It is caused by step-by-step solution the recurrent modified Maxwell’s equations, in analogies of DC formulations, for real and imaginary components of electric and vector magnetic potentials.<br />Conclusions. The elaborated new frequency adaptation method significantly expands possibilities of production design preparation for<br />powerful radio engineering systems. It allows using the software packages with a free license, reduces requirements to computing resources, reduces time costs and provides high precision in electromagnetic fields simulation. |
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Zaporizhzhya National Technical University 2018-05-29 13:24:17 |
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application/pdf http://ric.zntu.edu.ua/article/view/131558 |
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Radio Electronics, Computer Science, Control; No 1 (2018): Radio Electronics, Computer Science, Control |
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Copyright (c) 2018 D. S. Yarymbash, S. T. Yarymbash, M. I. Kotsur, D. O. Litvinov |
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