Engineering and Educational Technologies at Electrical and Computer Systems [Online journal].
Quarterly theoretical and practical journal. – Kremenchuk: KrNU, 2013. – Iss. 2/2013 (2). –
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Information - communication technologies at education

O. Chornyi, Yu. Lashko, T. Koval (download)
[in Ukrainian]

The features of the process of training engineering graduates in the current economic climate, the rapid development of computer technology, its hardware components, information and communication technologies. The main factor for the formation of professional skills defined laboratory practice. It is shown that the use of hardware and software and virtual systems in laboratory practice allows to train and retain professionals that meet modern requirements and are able to professionally involved in the design, debugging and operation of advanced electric drive systems and controls. The proposed systems are considered as self-contained computerized learning tools and can be used for various forms of study: full-time, part-time, distance, external studies.

Key words: training, engineering, laboratory training, virtual systems.

1. Vishnjakov Y.M., Rodzin S.I. The Virtual University: Myth or Reality? // Proceedings of the universities. Special Issue. Proceedings of the International Scientific and Technical Conference ISAPR. – Taganrog: TRTU, 2000. – № 2 (16). – РР. 275–282. [in Russian]

2. Krasilnikova V.A. Theory and technology of computer-based training and testing. Monograph. – Moscow: Dom pedagogiki, 2009. – 339 р. [in Russian]

3. Informatization of education: directions, facilities, technology: Textbook / Edited by S. Maslova. – Moscow: Publishing House of Moscow Power Engineering Institute, 2004. – 864 p. [in Russian]

4. Information systems of continuing education based on Internet technology / A.V. Dyachenko, V.G. Manzhula, A.E. Popov and oth. / Ed. A.E. Popov. – Moscow: Academy of Natural Science, 2010. – 130 p. – Available at: [in Russian]

5. Virtual laboratory systems and complexes – a new perspective for scientific research and improving the quality of training in electro / M.V. Zagirnyak, D.Y. Rodkin, O.P. Chornyi // Electromechanical and efficient system. – Kremenchug: KSPU, 2009. – Iss. 2/2009 (6). – PP. 8–12. [in Ukrainian]

6. Evstyfeev V.A. Problems of training in electrical systems using virtual // Transaction of the Kremenchug State Polytechnic University. – Iss. 4/2006 (39), part 1. – Kremenchuk: KSPU, 2006. – PP. 150–154. [in Russian]

7. Rodkin D.Y., Chornyi O.P., Yevstifeyev V.A. and oth. Virtual laboratory facilities for studies and research. Results and experience in development // Transaction of the Kremenchug State Polytechnic University. – Kremenchug: KSPU, 2008. – Iss. 3/2008 (50), part 1. – PP. 28–42. [in Ukrainian]

8. Chornyi O.P., Rodkin D.Y. Virtual systems and simulators – the technology of high quality training in the field of electromechanics, automation and control // High School: theoretical and practical issue. – 2010. – № 7, 8. – PP. 23–34. [in Ukrainian]

9. Evstifeev V.A., Chernyi O.P, Velichko T.V. Virtual package for the educational process and scientific research // Transaction of the National Technical University "Kharkiv Polytechnic Institute". Collected papers. Theme Issue "Problems of automated electric drive. Theory and Practice."– Kharkov: NTU "KhPI", 2005. – № 45. – РР. 25–28. [in Russian]

10. Menshikov D.V., Eichmann E.A., Yoon S.G. The main approaches to the development of the construction of virtual models and demonstrations // New educational technologies in high school: collection of materials Eighth International Scientific Conference, 2–4 February 2011. – Ekaterinburg: Ural Federal University, 2011. – PP. 373–378. [in Russian]

11. Postnikov E.B. An international survey creation and operation of remote access laboratories. – 2011. – Available at: [in Russian]

12. Non-verbal language and non-verbal thinking. – Available at: [in Russian].

Information systems and technologies. Mathematical modeling

А. Artemenko (download)
[in Ukrainian]

The main features of the laboratory stand using a computerized measuring complex have been formed. Static and dynamic characteristics of the twin-engine DC electric drive with a rigid connection of shafts have been shown. It is shown that the use of computerized laboratory model for experimental study of the electric drive is promising.

Key words: electric drive system, DC motor with separate excitation, a rigid connection of shafts, laboratory stand.

1. Gladyr A.I., Rodkin D.І., Zdor I.Ye. and oth. The possibilities of computerized measurement and diagnostic systems for solving electromechanics problems // Problems of creation of new machines and technologies. Collection of scientific papers KSPI. – Iss. 1/2000 (8). – Kremenchug: KSPI, 2000. – PP. 119–122. [in Russian]

2. Kalinov A.P., Gladyr A.I. Universal teaching and research equipment for electromechanical laboratories // Electromechanical and energy saving system. Quarterly research and production magazine. – Kremenchuk: KSPU, 2007. – Iss. 1/2007 (1). – PP. 14–19. [in Russian]

3. Kalinov A.P., Melnykov V.O., Artemenko A.M. Computerized laboratory complex to study electromechanical transmission of transport systems // Electromechanical and energy saving system. Quarterly research and production magazine. – Kremenchuk: KSPU, 2007. – Iss. 1/2010 (9). – PP. 50–53. [in Ukrainian].

A. Perekrest, I. Molodyka (download)
[in Russian]

Analyzed the problem of ensuring and control of the necessary microclimate for the room. Considered the question of complex automation and dispatching systems. Developed a computerized system for remote monitoring and control of the operating modes ventilation equipment for room 2105 department «Automatic control Systems and electric drive» Kremenchuk Mykhailo Ostrohradskyi National University. Developed an algorithm program for dispatching control and interface Labview.

Кey words: microclimate, local ventilation system, remote building, remote control unit.

1. Bondar Ye.S., Gordyenko А.S, Mykhailov V.A, Nimich G. Automation of ventilation and air conditioning: teaching aids. – Kyev: Avanpost–Prym, 2005. – 560 p. [in Russian]

2. Denisenko V.V. Computer control of the technological process, the experiment equipment. – M.: Gorachaya liniya–Telekom, 2009. – 608 p. [in Russian]

3. Calmakov А.A, Cuvshinov Y.A, Romanova S.S, Shelkunov S.A Automatics and automation of heat and ventilation:  teaching aids for students in higher education. – M.: Stroyisdat, 1986. – 479 p. [in Russian]

4. Perekrest A.L., Gulaya I.S. The non-standard room ventilation control system with heating // Electromechanical and energy saving systems. – Kremenchuk: KrNU, 2012. – Iss. 2, № 12. – PP. 116–121 [in Ukrainian]

5. Shulga Y.I., Cherniy A.P., Sukach S.V. To solving the problem of climate control in the premises of educational wound // Problems of labour protection in Ukraine. – K.: NNDIPBOP, 2010. – Iss. 19. – PP. 37–44. [in Ukranian]

6. Konoh I.S, Gula I.S., Perekrest A.L., Sukach S.V. Development and investigation intellectual control system for room’s microclimate’s parametrs // Electromechanical and energy saving systems. – Kremenchuk: KrNU, 2010. – Iss. 3, № 11. – PP. 80–85. [in Ukranian]

7. Sukach S.V. Development of Method and Control After Quality of Air Environment in Industrial Premises: dis. Cand. tech. science: 05.26.01. – Kyiv, 2011. – 20 p. [in Ukranian]

8. Sukach S.V.  Computerized systems of monitoring of educational facilities with the aim of creating a microclimate // Electromechanical and Energy Systems, Modeling and Optimization Methods. Conference proceedings of the 7 th International conference of students and young researches, Kremenchuk, April 02–04, 2009. – Kremenchuk: KrNU, 2009. – PP. 69–70. [in Ukranian]

9. Shulte R., Bridges B., Grimsrud D. Continuous monitoring of indoor air quality in schools // AВОК. – M.: ABOK–PRESS, 2005. – № 8. – PP. 36–48. [in Russian]

10. Cuvshinov Y., Mansurov R. The intelligent control system of microclimate formation processes of premises // AВОК. – M.: ABOK–PRESS, 2011. – № 8. – PP. 58–68. [in Russian]

11. Mkrtichan P. Automation and dispatching systems of ventilation // Technical science: theory and practice, Chita, April, 2012. – Chita: Molodoy ucheniy, 2012. – PP. 28–30. [in Russian]

12. Andrushenko A.A., Vodichev V.A. Electronic programmable relays series of Easy and MFD–Titan. – Odessa: DP Muller Electric, 2006. – 223 p. [in Ukranian]

13. Batalin G., Vasutinskyi V. Creation of a distributed data acquisition systems on the basis of the standard OPC // Modern technologies of automation. – M.: EKSMO, 2005. – № 2. – PP. 84–87 [in Russian]

14. Patrahin V., Kravets М. Technology Data Socket Connection as a universal means of a network of exchange in the Labview // Pikad. – Kyiv: Pikad, 2004. – № 2. – PP. 84–87. [in Ukranian]

15. Muravyov S.V., Komarov A.V., Savolainen V. Graphic measurement programming and creation of laboratory works for engineering education // Proceedings of the XVI IMEKO World Congress, September 25–28, 2000. – Austria: Vienna. – Iss. 2. – PP. 73–79.

Electrotechnical complex and systems. Energetics

M. Volzhan, A. Perekrest (download)
[in Russian]

The basic scheme of reconstruction of the heating units and ventilation systems of buildings the public sector through the use of the variable speed drive systems, process automation and the use of alternative energy sources (solar and low-grade heat sources). The algorithm of interaction and performance of individual units within a single system to ensure efficient operation. It is noted that the proposed scheme is universal and can be used for any building, taking into account the characteristics and conditions of the implementation of development.

Key words: alternative energy heating system.

1. Vasiliev G.P. Heating and cooling buildings with low-grade thermal energy of the surface layers of the Earth. – M.: Krasnaya zvezda, 2006. – 220 p.

2. Vasiliev G.P., Hrustachev L.V., Rosin A.G., Abuev I.M. Guidance on the application of heat pumps using secondary energy resources and renewable energy sources. – M: GUP "NIAC", 2001. – 66 p.

3. Lykov A.V. Heat and mass transfer: Handbook. – M: Energetic, 1987. – 480 p.

4. Lantukh N.M., Shcherbaty V.S., Ageev G.M. Combined solar-electric heating system.

– 2006. – 20 p.

D. Rodkin, D. Mosyundz (download)
[in Russian]

Class of identification problems continuously expanded mainly due to the increasing needs because of growth of features and class of solved technical and technological problems. The Problem of Identification this is the definition of the parameters a wide variety of electrical electromechanical systems. With regard to an electromechanical device that is a definition of electromechanical and electromagnetic parameters of electrical machines. Every year appears more than two hundred works devoted the mentioned scientific and technical task. The range of methods of the parameters identification of electrical equipment is extremely wide, from the simplest, based on elementary ideas about physical processes and equivalent circuits to complex, based on complex mathematical models of devices and systems.

The analysis shows that the greatest interest of researchers cause different versions of frequency methods, particularly those where the notions of the processes supported by models of energy processes mainly in the frequency domain. Such studies are devoted to sufficiently large list of the results of studies carried out at the Kremenchuk Mykhailo Ostrohradskyi National University. The peculiarity of this work is that with sufficient wide range of use of frequency representations in solving specific problems (different frequency power supply of the motor windings, poly-harmonic voltage, pseudo polyharmonics  supply, the use of pseudo sources  of AC voltage, etc.) are using an original promising energy method, which is based on the use of energy balance equations components of the instantaneous power consumption of power supply and elements of the equivalent circuit of the electric machine, which takes into account any physical phenomena. Energy balance method applies to equivalent circuits of machines of alternating and direct current of any complexity. The importance and the prospect the method under consideration that it applies not only for the identification of electric circuits, but tools and machines with other energy conversion principles with linear and nonlinear characteristics.

Key words: instantaneous power method, energy balance, identification equations and systems.

1. Zagirnyak M.V., Rodkin D.I., Chernyi A.P. Direction of development of the theory of instantaneous power and its application in problems of electrical engineering // Intern. Scientific and Technical. conf. "Problems of automated electric. Theory and Practice". – Odessa, 2011. – PР. 347–354. [in Russian]

2. Rodkin D.I., Mosyundz D.A., Cherniy A.P., Korenkova T.V. Enhancement capabilities of energy method in task of identification nonlinearity of electromechanical system // Electromechanical and energy saving systems. – 2012. – Iss. 2/2012 (18). – PP. 10−17. [in Russian]

3. Rodkin D.I., Romashihіn J.V. Energy method of electro-mechanical devices and systems identification // Proceedings of the institutions of higher education associations and Energy CIS. Energy. – Minsk, 2011. – Iss. 3. – PP. 10–20. [in Russian]

4. Rodkin D.I., Romashihіn J.V. Energy diagnosis of induction machines // Bulletin of the Kremenchuk Michailo Ostrohradskiy State University. – Kremenchug: KSU, 2010. – Iss. 3 (62), рart 2. – PP. 128–137. [in Russian]

5. Rodkin D.I., Kalinov A.P., Romashihin J.V. The development of frequency methods for estimating the parameters of alternating current motors // Journal KSPU. Collection Science works of KSPU. – Kremenchug: KSPU, 2005. – Iss. 3/2005 (33). – PP. 43–47. [in Russian]

6. Rodkin D.І. Features of the application of the energy method of identification of AC motors with pseudo polyharmonic signals // Electromechanical and efficient system. – Kremenchug: KSPU, 2009. – Iss. 1/2009 (5). – PP. 7–20. [in Russian]

7. Rodkin D.І. Current problems of theory and practice of Energy Saving electromechanical systems // Journal KSPU . – Iss. 3/2008 (50), рart 1. – PP. 8–17. [in Russian]

8. Romashihin Y.V. Estimation of efficiency of using of pseudo polyharmonic signals of different forms in the identification of parameters of induction motors // Electromechanical and efficient system. Quarterly research and production magazine. – Kremenchug: KrNU, 2013. – Iss. 1/2013 (21). – PP. 58–67. [in Russian]

9. Rodkin D.I. Commentary on the theory of energy processes with polyharmonic signals. Part 2. The definition and use of indicators of the energy modes. // News of Kremenchuk State polіtechnіc unіversety: scientific study KSPU. – 2005. – Іss. 3/2005 (32). – PP. 106–115. [in Russian]

10. Rodkin D.I., Byalobrzhesky A.V., Lomonos A.I. Indicators of energy process in circuit with polyharmonic voltage and current // Journal of Electrotechnology. – 2004. – Iss. 6. – PP. 37–41. [in Russian]

11. Tonkal V., Novoseltsev A., Denisyuk S. The energy balance in power circuits. – Kyiv: Naukova dumka, 1992. – 312 p. [in Russian]

12. Rodkin D.I., Romashihіn Y.V. Evaluating the effectiveness of the energy method of parameter identification of induction motors with pseudo polyharmonic voltage and current signals // Proceedings of the Thirteenth International scientific conference "Problems saving in electrical systems. Science, education and practice."– Kremenchug: KNU., 2011. – Iss. 1/2011 (1). – PP. 292–293. [in Russian]

13. Rodkin D.I. On the inconsistency some theory of the energy processes to Telledzhen’s theorem // Problems of automated electric. Theory and practice. − Kharkov: NTU "KhPI", 2010. – № 28. – PP. 127−135. [in Russian]

14. Rodkin D.I. Balance of components of the instantaneous power of polyharmonic signals // Visnyk KDPU: Naukovi pratsi KDPU. – 2007. – Iss. 3/2007 (44). – PP. 66–77. [in Russian]

15. Akagi H., Watanabe E.H., Aredes M. Instantaneous Power Theory and Applications to Power Conditioning  – New York: Wiley, 2007. – 380 p.

16. Gzarnecki L. Comments on Active Power Flow and Energy Accounts In Electrical Systems With Nonsinusoidal Waveforms and Assymetry. // IEEE Transactions on Power Delivery. – 1996. – Iss. 11/1996 (3). – PP. 1244–1250.

17. Krogeris A.F., Rashevits K.K., Treimanis E.P. Power of alternating current. – Riga: Fiz. energy. Inst. Latvia Academy of Sciences, 1993. – 294 p. [in Russian]

18. Jemerov G. Instantaneous and average active and reactive power in linear circuits with sinusoidal voltages // Problems of automated electric. Theory and Practice. – Kharkov: NTU "KhPI", 2004. – № 43. – PP. 153–160. [in Russian]

19. Rodkin D.I. Decomposition of power components of polyharmonic signal” // Journal of Electrical Engineering. – 2003. – Iss. 6. – PP. 34–37. [in Russian]

20. Rodkin D.I., Romashihin Yu.V. Parameter identification of induction motors with a pseudo polyharmonic action // Electric drives AC: Proceedings of the Fifteenth International STC. – Ekaterinburg, 2012. – PP. 67–72. [in Russian]

21. Rodkin D.I. Instantaneous power of three phase motorload with poly harmonic voltage and current // Elektroinform. – 2007. – № 4. – PP. 10–13. [in Russian]

22. Jemerov G. System components of the total power and energy coefficients based on p-q-r theory of power // Technical Electrodynamics, special issue. Problems of modern electronics. – 2004. – Part 1. – PP. 69–74. [in Russian]

23. Akagi H., Kanazava Y., Nabae A. Theory of the instantaneous reactive power in three-phase circuits // Int. Power Electronics Conf., Tokyo, Japan, IPEC’83, 1983. – PP. 1375–1386.

24. Dugan R.C., McGranaghan M.F., Beaty H.W. Electrical power systems quality. – McGraw-Hill, 1996. – 265 p.

25. Kim K., Blaabjerg F., Bak B. Jensen Spectral analysis of instantaneous powers in single-phase and three-phase systems with use of p-q-r theory // IEEE Trans. on Power Electronics. – 2002. – Iss. 17/2002 (5). – PP. 711–720.

26. Alonge F., D’Ippolito F., Ferrante G., Raimondi F.M.. Parameter identification of induction motor model using genetic algorithms // IEEE, Dept. of Power Eng. – 2002. – Iss. 2. – PP. 1199–1203.

27. Hasegawa M., Ogawa D., Matsui K. Parameter Identification Scheme for Induction Motors Using Output Inter-Sampling Approach // Asian Power Electronics Journal. – 2008. – Iss. 2/2008 (1). – PР. 15–22.

28. Steven R. Shaw. Numerical methods for identification motor parameters. – Massachusetts institute of technology, 1997. – 223 p.

29. Gastli A. Identification of induction motor equivalent circuit parameters using the single-phase test // IEEE Transactions on Energy Conv. – March 1999. – Iss. 14, № 1. – PР. 51–56.

30. Rodkin D.I. About the need to separate the concepts of quality and consumption of energy conversion // Bulletin of the Kremenchuk State Polytechnic University: research papers KSPU. – Kremenchug: KSPU, 2003. – Iss. 2/2003 (19), part 1. – PP.143–148. [in Russian]

31. Rodkin D.I., Korenkova T.V. The energy method for analyzing the controllability of electromechanical systems // Electromechanical and efficient system. – 2010. – Iss. 2/2010 (10) – PP. 8–16. [in Russian]

32. Agunov M.V., Agunov A.V. About energy ratios in electrical circuits with non-sinusoidal modes // Electricity. – 2005. – № 4. – PP. 53–56. [in Russian]

33. Husainov Sh.N. Power characteristics of the non-sinusoidal modes // Electricity. – 2005. – № 9. – PP. 63–70. [in Russian]

34. Rudenko N.A., Romashihin Yu.V. By definition psevdopoligarmonical signals for harmonic analysis [Electronic resource] // Engineering and educational technologies at electrical and computer systems. Quarterly theoretical and practical journal. – Kremenchuk: KrNU, 2013. – № 1/2013 (1). – PP. 31–47. – Available at: [in Russian]

35. Nussbaumer G. Fast Fourier Transform and calculating convolution algorithms. – M.: Radio i svyaz, 1985. – 248 p. [in Russian]

36. Sigorsky V. Mathematical apparatus of engineer. – Kiev: Tehnika, 1977. – 768 p. [in Russian]

37. Baskakov S. Radio Circuits and Signals. – M.: Vysshaya shkola, 1988. – 450 p. [in Russian].

I. Konokh, M. Bazyshyn (download)
[in Ukrainian]

The work refers to the positional control systems of industrial robots and can be used for upgrading or creating an adaptive control system of a robot manipulator PUMA–560 with improved transients and high accuracy positioning in conjunction with power modules AWD–10–36 and industrial computers.

The device reads the signals of current sensors and position sensors, the calculation of control actions and the formation voltage for links robot manipulator drive. Improved accuracy in dynamic mode is achieved by modifying the coefficients of the PID-controller position when moving from one to another part of the trajectory.

The device performs the surveillance system as a whole, manages and controls the movement of a robotic manipulator, provides independent control of speed and position of each drive separately, forms control impact power converters with the limitations of the manipulator position in space, providing two-way communication with industrial PC.

Кey words: robot-manipulator, control provisions.

1. Repetsky V.A. Fuzzy tracking control system of a robotic arm with the function of the inverse kinematic problem // Electromechanical and Power Systems, methods of modeling and optimization. Collection of Science works XI International scientific and technical conference of Young Scientists and Specialists, 9–11 April 2013. – Kremenchuk: KrNU, 2013. – PP. 249–250. [in Russian]

2. Omatu S., Khalid M., Yusof R. Neuro-Control and its application. Corrected edition, Springer: 1996. – 255 р. – ISBN: 3540199659.

3. Jurevich E.I. Fundamentals of Robotics. – St. Petersburg: BHV–Petersburg, 2005. – 415 p. [in Russian]

4. Industrial robot RM–01. Hardware Guide. [in Russian]

5. The control unit is a DC motor commutator AWD10. Instruction manual. – Moscow: ZAO «Laboratoriya Elektroniki», 2011. – 45 p. [in Russian]

6. Armstrong B., Khatib O., Burdick J. The Explicit Dynamic Model and Inertial Parameters of the PUMA 560 Arm // Proceedings. 1986 IEEE International Conference on Robotics and Automation, 1986.

Ecology and environmental safety. Vital safety and labor protection

V. Nozhenko, L. Boyko, G. Yudina (download)
[in Russian]

Indoor air composition and its negative effects on human health are described. The definition of properties of houseplants, which are useful for health and vital activity of human. The list of plants, that are best to grow in study and science laboratories, is given. The data of plants, that reduce the general containment of the microbiological cells in the air and absorb the toxic substances, are given in the article.

Key words: houseplants, air composition, phytoncidic properties of plants, microclimate of the closed rooms.

1. The benefits of houseplants [Electronic resource]. – Available at: [in Russian]

2. Kislyakov P. Formation of ecology safe educational environment of high school [Electronic resource]. – Available at: [in Russian]

3. Krestinina N., Sorokopudov V., Sorokopudova O. Investigation of the influence of gardening on the parameters of indoor environment [Electronic resource]. – Available at: [in Russian]

4. Kuzmina-Medova E. Plants in the interior // Problems green building garden economy. – Novosibirsk, 1972. – PP. 115–117. [in Russian]

5. Sulejmanova Z. The use of tropical and subtropical plants to improve the quality of indoor air // Vestnik Orenburg State University, 2009. – № 6. – PP. 519–522. [in Russian]

6. Improving of home environment with houseplants [Electronic resource]. – Available at: [in Russian]

7. Tokin B. Medicinal plants Poisons. Tale about the fitosides. – L.: Publisher Leningrad University, 1980. – 280 p. [in Russian]

8. Kazarinova N., Tkachenko K. Health is given by houseplants. – SPb.: Publishing house «Neva», 2003. – 128 p. [in Russian]

9. Nekrasova M., Krestinina N. Methods of environmental management. Medical and ecology fitodesign: methodological manual. – M., 2004. – 174 p. [in Russian]

10. Domashov I., Korotenko V., Kirilenko A., Postnova E. Household ecology. – Bishkek, 2004. – 300 p.

O. Chornyi, V. Nykyforov, D. Rodkin, V. Nozhenko (download)
[in Russian]

Main sources of electromagnetic radiations with natural or anthropogenic origin are considered. Possible changes in humans’ organism caused by the high- and low-frequency radiations and methods of protection against it are given. The characteristics of the most common sources of electromagnetic field that influences on every human is stated. The devices for the measurements of electromagnetic field are presented. The prospects of research aimed at harmonization and optimization of international and national standards of maximum permissible levels of exposure to electromagnetic radiation on man and biota are discussed.

Key words: electromagnetic field, the sources of electromagnetic radiation, exposure to humans and biota, the legal limit.

1. Selivanov S., Filenko V., Bazhynov A., Budianskaya E. Electromagnetic biosphere pollution by motor transport (vehicles, electric vehicles, hybrid vehicles) // Automobile transport: a collection of scientific papers. – 2009. – № 25. – PP. 24–32. [in Russian]

2. Influence of electromagnetic fields [Electronic resource]: – Available at: [in Russian]

3. Maletkin V., Nekrutenko V., Golyaev I. Biophysics of the influence by electromagnetic flap of the land on person with standpoint of safety to vital activity // Transactions of the Volodymyr Dahl East Ukrainian National University. – 2011. – № 11 (165), part. 2. – PP. 165–169. [in Russian]

4. Shevchenko S. Electromagnetic interference power equipment on the environment [Electronic resource]. – Available at: [in Russian]

5. Kuraev G., Voynov V., Morgalev Yu. Influence of electromagnetic radiation personal computers on the human organism [Electronic resource]. – Available at:$file/9_15Kuraev.pdf [in Russian]

6. Savytskaja Y., Paslyon V. The influence of the mobile phone’s high electromagnetic field on human’s organism // Ecology and Noosferolohiya. – 2009. – № 1, 2. – Iss. 20. – PP. 38–43. [in Russian]

7. Savytskaja Y., Paslyon V. The influence of high-frequency electromagnetic fields on living organisms // Ecology and noosferolohiya. – 2009. – № 3, 4. – Iss. 20. – PP. 47–50. [in Ukraine]

8. Martynyuk V., Tseyslyer Yu., Temuryants N. Interference of mechanism of weak extremely low frequency electromagnetic fields influence on man and animals // Geophysical processes and the Biosphere. – 2012. – № 2. – Iss. 11. – PP. 16–39. [in Russian]

9. Tihankov N., Tihankov E., Pleshko E. Information Methods Neutralize the Negative Influence of «Electromagnetic Smog» // Scientific Transactions of International Humanitarian University: a collection of scientific papers. Series “Information Technology and Project Management”. – Odessa. – 2012. – № 4. – PP. 83–85. [in Russian]

10. Cherniy O., Nykyforov V. Electromagnetic compatibility electromechanical and biological systems // Engineering and Educational Technologies at Electrical and Computer Systems. – Kremenchuk: KrNU, 2013. – № 1 (1). – PP. 140–149. [Electronic resource]. – Available at: [in Russian]

11. Podobed I. On the opposite properties of the same radiation and its effects on employee // Problems of safety in Ukraine: collection of scientific papers. – Kyiv. – 2012. – № 23. – PP. 90–95. [in Ukraine]

12. Adie U., Delgado H., Holodov Yu. Electromagnetic pollution of the planet and the health of // Science and Humanity: International Yearbook. – Moscow, 1989. – PP. 10–18. [in Russian]

13. Bise W. Lower power radio-frequency and microwave effects on human electroencephalogram and behavior // Physiol. Chem. and Physics. – 1978. – Iss. 10. – PP. 387–398.

14. Burlaka N., Gozhenko S. Electromagnetic field, his kinds, descriptions, classification and influence on population’s health // Actual problems of transport medicine. – 2010. – № 4. – Iss. 2 (22). – PP. 24–32. [in Russian]

15. Oleshko T. System approach to cellular components influence on the environment [Electronic resource]. – Available at: [in Ukraine]

16. Bezverkhaya A. Hygienic estimation of the influence of electromagnetic radiation on the human body and animals // Hygiene of populated places: a collection of scientific papers. – Kyiv, 2009. – № 53. – PP. 228–231. [in Russian]

17. Grachev N. Biomedical effects of electromagnetic radiation [Electronic resource].– Available at: [in Russian]

18. Nikitina N., Barkevich V. The influence of electromagnetic radiations on health of population // Hygiene of populated places: a collection of scientific papers. – Kyiv, 2007. – № 50. – PP. 209–214. [in Ukraine]

19. Kovaleva A. The influence of anthropogenic origin electromagnetic fields on human organism // Transactions of Zaporizhzhya National University: a collection of scientific papers. Biological Sciences. – Zaporozhye, 2009. – № 2. – PP. 96–104. [in Ukraine]

20. Kovaleva A. The influence of electromagnetic fields and radiations on bioobjects (the literary review) // Current issues of biology, ecology and chemistry: electronic scientific editions. – 2009. – № 1. – Iss. 1. – PP. 64–85. [in Russian]

21. Lyashenko G., Cherepnev I., Polyanova N. Determination of approaches to setting the norms of influence of electromagnetic fields on the environment [Electronic resource]. – Available at: [in Russian]

22. ICNIRP Guidelines for limiting exposure to varying electric, magnetic and electromagnetic fields (300 GHz) [Electronic resource]. – Available at: [in Russian]

23. SSN № 239–96. State sanitary norms and rules protecting people from exposure to electromagnetic radiation. – Kiev, 1996. – 28 p. [in Ukraine]

24. State standard 12.1.002–84. Power frequency electric fields. Permissible levels of field strength and requirements for control at work-place. [in Russian]

25. State standard 12.1.006–84. Electromagnetic fields of radio frequencies. Permissible levels at work-places and requirements for control. [in Russian]

26. State sanitary rules and norms–98. State sanitary rules and norms of work with visual display terminals computers. [in Ukraine]

27. State sanitary rules and norms 3.3.6–096–2002. State sanitary rules and regulations when dealing with sources of electromagnetic fields. [in Ukraine]

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Results of work and development prospects of the scientific directions

N. Gordienko (download)
[in Ukrainian]

The material relating to the Institute of Electromechanics, Energy Saving and Control Systems of Kremenchuk Mykhailo Ostrohradskyi National University XIV International Scientific and Practical Conference «Problems of energy saving in electrical systems. Science, Education and Practice», which reflects the important stages of a major international forum: plenary session, the VII specialized exhibition «Modern technologies in education and industry», reports on completed the dissertation work, the performances of young scientists. There was a high level of organization of the event and expressed the hope that the conference will be further developed and will be new and effective forms of its implementation.

Key words: scientific and practical conference, plenary session, specialized exhibition.

1. Report of the XIV International Scientific and Practical Conference «Problems of energy saving in electrical systems. Science, education and practice». – Kremenchuk, KrNU, 2013. – 10 p. [in Ukrainian]

2. Electromechanical and energy saving systems. Theme Issue «Challenges automated electric. Theory and Practice». – Kremenchuk: PP Shcherbatykh A.V., 2013. – Iss. 2/2013 (22), part 2. – 455 p. [in Ukrainian].