        TY  - JOUR
TT  - MODEL OF STUDYING ELECTROMAGNETIC FIELD AND WAVES THEORY VIA COMPUTER SIMULATION
AU  - Bzhalava, Tamar
AU  - Kervalıshvılı, Paata
AU  - Tsırekıdze, Mzia
AU  - Kakabadze, Goga
PY  - 2016
DA  - May
JF  - The Eurasia Proceedings of Educational and Social Sciences
JO  - EPESS
PB  - ISRES Publishing
WT  - DergiPark
SN  - 2587-1730
SP  - 57
EP  - 63
VL  - 4
KW  - Electrodynamics
KW  - wave scattering
KW  - simulation
N2  - Model of studying the electromagnetic theory, mathematics, computing anddata visualization in purpose to comprehend the main ideas of theories andpractical applications are proposed. To learn physical processes and system’sproperties by computer simulation and to learn simulation by solution ofphysical tasks is the concept of proposed model. Integrated course ofelectromagnetic (EM) field and wave theories, mathematical solution ofequations, computing techniques based on solutions of well known tasks as wellas current problems of applied electrodynamics are considered. Application examples of electromagnetic in scientific research, moderntechnologies represent the abstract theories in realistic existence, help tounderstand deeply theoretical course, appreciate significance of (EM) theoriesin many fields of daily life.&amp;nbsp; Knowledge of maintheories of electromagnetic combined with mathematics and computing isnecessary for solving the electrodynamics problems such as (EM) wavesscattering and diffraction, interaction of (EM) field and objects of differentelectric and geometric properties, basis of linear and nonlinear opticaltechniques, etc. Selectedtasks of electrodynamics are constructed of several modules: formulation ofphysical problem, theories and methods of solution – physical and mathematical,specifics of problem, approximation and application cases, computer simulation,analysis. Each completed module expands outlook, develops skills, intuition, self-confidence, encouragesparticipants be more motivated, active in learning and improvement of knowledgein multi disciplines. Proposed model is presented by consideringone task - EM waves scattering on a single cylindrical body, applicable in radio physics, transmitting and detecting systems, aerosol studies for particles ofdifferent origin. Estimation of EM field components, scatteringcharacteristics, theoretical predictions based on analyticalsolutions and numerical simulations are considered.&amp;nbsp;
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Visser, H., (2012). Antenna Theory and Applications, John Wiley &amp; Sons, Inc., Chichester, UK.
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Fundamentals and applications in aerosol spectroscopy. (2011). edited by Ruth Signorell, Jonathan P. Reid. by Taylor &amp; Francis Group, LLC. CRC Press. 
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Kervalishvili, P. J., Bzhalava, T. N., (2016). Investigations of spectroscopic characteristics of virus-like nanobioparticles, American Journal of Condensed Matter Physics, 6 (1),7-16. 
Bzhalava T.N., (1990). Thesis: Plane E- and H- polarized electromagnetic waves scattering on the system of two and three cylinders of different electric properties. A dissertation presented in fulfilment of the requirements for the degree Candidate (PhD) of Physics and Mathematics Sciences. Tbilisi State University, Georgia.
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Ermolina, I., Morgan, H., Green, N. G., Milner, J. J., Feldman, Yu. (2003). Dielectric spectroscopy of tobacco mosaic virus. Biochimica et Biophysica Acta, 1622, 57–63. doi:10.1016/S0304-4165(03)00118-1.
UR  - https://dergipark.org.tr/en/pub/epess/issue//332409
L1  - https://dergipark.org.tr/en/download/article-file/331366
ER  -