Technical and Economic Aspects of Improving the Processes of Manufacturing Laser Gyroscopes Using Methods of Computer Simulation
( Pp. 36-49)
Kuznetsov Evgeny V.
Dmitry N. Ermakov
Samusenko Oleg E.
Golyaev Yuri D.
Kolbas Yuri Yu.
Kofanov Yuri N.
Soloveva Tatyana I.
Kuznetsov Nikita E.
Vinokurov Yuri A.
More about authors
Kuznetsov Evgeny V.
Dr. Sci. (Eng.), Professor; General Director; Head at the Center
Research Institute “Polyus” named after M.F. Stelmakh; Engineering Academy of the Peoples’ Friendship University of Russia
Moscow, Russian Federation Dmitry N. Ermakov Dr. Sc. (Polit.), Dr. Sc. (Econ.), Cand. Sci. (Hist.), Professor, Principal Researcher; Institute of China and Modern Asia, Russian Academy of Sciences Researcher; Russian Federation; Professor of the Department of Management
Center for World Politics and Strategic Analysis; International Academy of Business and New Technologies
Institute of China and Modern Asia, Russian Academy of Sciences Researcher, Russian Federation; Yaroslavl, Russian Federation Samusenko Oleg E. kandidat tehnicheskih nauk, docent; direktor departamenta innovacionnogo menedzhmenta v otraslyah promyshlennosti
Engineering Academy of the Peoples’ Friendship University of Russia
Moscow, Russian Federation Golyaev Yuri D. Dr. Sci. (Eng.); Head at the NPK-470
Research Institute “Polyus” named after M.F. Stelmakh
Moscow, Russian Federation Kolbas Yuri Yu. Dr. Sci. (Eng.); Deputy Head at the NPK-470
Research Institute “Polyus” named after M.F. Stelmakh
Moscow, Russian Federation Kofanov Yuri N. doktor tehnicheskih nauk, professor; glavnyy nauchnyy sotrudnik; professor
Research Institute “Polyus” named after M.F. Stelmakh; National Research University Higher School of Economics
Moscow, Russian Federation Soloveva Tatyana I. Cand. Sci. (Eng.), Associate Professor; leading researcher
Research Institute “Polyus” named after M.F. Stelmakh; Engineering Academy of the Peoples’ Friendship University of Russia
Moscow, Russian Federation Kuznetsov Nikita E. aspirant
Research Institute “Polyus” named after M.F. Stelmakh
Moscow, Russian Federation Vinokurov Yuri A. nachalnik laboratorii
Research Institute “Polyus” named after M.F. Stelmakh
Moscow, Russian Federation
Research Institute “Polyus” named after M.F. Stelmakh; Engineering Academy of the Peoples’ Friendship University of Russia
Moscow, Russian Federation Dmitry N. Ermakov Dr. Sc. (Polit.), Dr. Sc. (Econ.), Cand. Sci. (Hist.), Professor, Principal Researcher; Institute of China and Modern Asia, Russian Academy of Sciences Researcher; Russian Federation; Professor of the Department of Management
Center for World Politics and Strategic Analysis; International Academy of Business and New Technologies
Institute of China and Modern Asia, Russian Academy of Sciences Researcher, Russian Federation; Yaroslavl, Russian Federation Samusenko Oleg E. kandidat tehnicheskih nauk, docent; direktor departamenta innovacionnogo menedzhmenta v otraslyah promyshlennosti
Engineering Academy of the Peoples’ Friendship University of Russia
Moscow, Russian Federation Golyaev Yuri D. Dr. Sci. (Eng.); Head at the NPK-470
Research Institute “Polyus” named after M.F. Stelmakh
Moscow, Russian Federation Kolbas Yuri Yu. Dr. Sci. (Eng.); Deputy Head at the NPK-470
Research Institute “Polyus” named after M.F. Stelmakh
Moscow, Russian Federation Kofanov Yuri N. doktor tehnicheskih nauk, professor; glavnyy nauchnyy sotrudnik; professor
Research Institute “Polyus” named after M.F. Stelmakh; National Research University Higher School of Economics
Moscow, Russian Federation Soloveva Tatyana I. Cand. Sci. (Eng.), Associate Professor; leading researcher
Research Institute “Polyus” named after M.F. Stelmakh; Engineering Academy of the Peoples’ Friendship University of Russia
Moscow, Russian Federation Kuznetsov Nikita E. aspirant
Research Institute “Polyus” named after M.F. Stelmakh
Moscow, Russian Federation Vinokurov Yuri A. nachalnik laboratorii
Research Institute “Polyus” named after M.F. Stelmakh
Moscow, Russian Federation
Abstract:
The article discusses ways to improve the quality and economic efficiency of the development and production of complex innovative electronic devices, which include laser gyroscopes (LGs). The problems arising in ensuring the reliable operation of the LG in a wide temperature range, associated with the dense arrangement of the device, are described. The theoretical principles and mathematical apparatus that are used in the construction of thermal models of triaxial LGs with electronics are considered in detail. A developed algorithm for constructing a thermal model of an LG, which provides for a gradual disaggregation (zooming) procedure, is presented. The process of modeling the LG using the ASONIKA system is described, the constructed thermal model of the LG is presented, as well as the thermal field of one of the printed circuit assemblies of the LG. The detected thermally loaded electronic components are indicated. The results of experimental verification of the accuracy of modeling by means of real measurements by temperature sensors of temperatures in the nodes of the model, which have confirmed the reliability of thermal modeling using the ASONIKA system, are presented. It is emphasized that the cost of manufacturing and testing LG is quite high. Therefore, the task of finding ways to reduce the cost at the stages of development and production of LG while ensuring an increase in the quality and reliability of manufactured devices is extremely urgent. Accurate thermal modeling at early stages of development is an effective way to solve this problem due to savings in testing and redesign costs, as well as due to the use of an inexpensive domestic computer simulation system ASONIKA.
How to Cite:
Kuznetsov E.V., Dmitry N.E., Samusenko O.E., Golyaev Y.D., Kolbas Y.Y., Kofanov Y.N., Soloveva T.I., Kuznetsov N.E., Vinokurov Y.A., (2021), TECHNICAL AND ECONOMIC ASPECTS OF IMPROVING THE PROCESSES OF MANUFACTURING LASER GYROSCOPES USING METHODS OF COMPUTER SIMULATION. Computational Nanotechnology, 3 => 36-49.
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Lukyanov D., Filatov Yu., Golyaev Yu. et al. 50th anniversary of the laser gyro. 20th Saint-Petersburg International Conference on Integrated Navigation Systems. ICINS 2013. Pp. 36-49.
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Okada H., Liu C., Ninomiya T. et al. Analysis of particulate composite materials using an element overlay technique. CMES: Computer Modeling in Engineering Sciences. 2004. Vol. 6. No. 4. Pp. 333-348.
Raja B., Praveenkumar V., Leelaprasad M., Manigandan P. Thermal simulations of an electronic system using ansys icepak. Int. Journal of Engineering Research and Applications. 2015. Vol. 5. Issue 11 (Part 1). Pp. 57-68.
Shalumov A.S., Kofanov Yu.N., Uvaysov S.U. et al. Automated system ASONIKA for modeling of physical processes in radioelectronic devices with considering of outer influences. Moscow: Radiotekhnika, 2013. 424 p. (In Rus.)
Shafic S.I., Velez G., Toro C. et al. Designing Intelligent Factory: Conceptual Framework and Empirical Validation. ISSE 2017. 40th International Spring Seminar on Electronics Technology. Red Hook, USA: IEEE Computer Society, 2017. Pp. 1801-1808.
Stroganov A., Zhadnov V., Polesskii S. Review of software complexes for reliability calculation of complicated technical systems. Components and Technologies. 2007. No. 5. Pp. 183-190.
Sukhanov V.O., Kukartsev V.V. Actuality of CALS-technologies application at the engineering enterprises of Russia. Actual Problems of Aviation and Cosmonautics. 2011. Vol. 1. No. 7. Pp. 466-467.
Udalov A.I. Thermal designing of radioelectronic devices. Moscow: MIREA, 2007. 211 p. (In Rus.)
Yovanovich M.M. Four decade of research on thermal contact, gap, and joint resistance in mictroelectronics. IEEE Trans. CPMT, 28. 2005. Pp. 182-206.
Aldham S. Five common misconceptions about thermal design. 2017. https://thermalconference.com
Belov A., Soloveva T. Intellectual ring laser quality control sys-tem - key component of ring lasers science-based production. 20th International Conference KES-2016 on Knowledge-Based and Intelligent Information and Engineering Systems (York, England, September 4-7 2016). Procedia Computer Science. 2016. Vol. 96. Pp. 456-464.
Belov A., Vnukov A., Soloveva T. Complex education program Project Seminar to meet today and tomorrow needs of fast developing optical-electronic industry. ISSE 2017. 40th International Spring Seminar on Electronics Technology. Red Hook, USA: IEEE Computer Society, 2017. Pp. 1-7.
Cook B. Slashing PCB design cycle time using real-time pcb thermal analysis tools. 2017. https://thermalconference.com
Cheng H.C., Yu C.Y., Chen W.H. An effective thermal-mechanical modeling methodology for large-scale area array typed packages. Computer Modeling in Engineering Sciences. 2005. Vol. 7. No. 1. Pp. 1-17.
Chirkin M.V., Klimakov V.V., Ulitenko A.I., Molchanov A.V. Passive controlling of a temperature field inside strapdown inertial navigation system. Proceedings of 18th St.-Petersburg International Conference on Integrated Navigation Systems. 30 May - 1 June, 2011. Pp. 122-124.
Kandalov P.I., Madera A.G. Mathematical and computing modeling of temperature fields in electronic modules. Proc. 16th Intern. Workshop on Thermal Investigations of ICs and Systems (THERMINIC). IEEE. Barselona, October 6-8, 2010.
Kofanov Yu.N. Theoretical basement of designing, technology and reliability of radioelectronic devices. Moscow: Radio i svyaz. 1991. 360 p. (In Rus.)
Kofanov Yu.N. Automated system ASONIKA in designing of radio-electronic devices. Moscow: MIEM NRU HSE. 2012. 58 p. (In Rus.)
Kofanov Yu.N., Sotnikova S.Yu., Lemanskiy D. Method of computer modeling accuracy increase for electronic means based on inter-connection of different physical processes proceeding. In: Innovative information technologies: Materials of the international scientific-practical conference. S.U. Uvaysov (ed.). Part 2. Moscow: HSE, 2014. Pp. 616-620.
Kofanov Yu.N., Vinokurov Yu.A., Sotnikova S.Yu. Optoelectronic devices thermal working modes providing method. International Seminar on Electron Devices Design and Production (SED 2019), Prague.
Kuznetsov E., Kolbas Yu., Kofanov Yu. et al. Method of computer simulation of thermal processes to ensure the laser gyros stable operation. ICCES 2019 International Conference on Computational Experimental Engineering and Sciences (Tokyo, 24-28 March, 2019). Conference Abstract. Co-sponsored by Tech Science Press, 2019.
Kuznetsov E., Kolbas Yu., Kofanov Yu. et al. Method of computer simulation of thermal processes to ensure the laser gyros stable operation. In: Computational and experimental simulations in engineering. H. Okada, S. Atluri (eds.). ICCES 2019. Mechanisms and Machine Science. Vol. 75. Springer, Cham. 2020. Pp. 295-300.
Li Geng, Zhang Pengfei, Wei Guo et al. Multiple-point temperature gradient algorithm for ring laser gyroscope bias compensation. Sensors (Basel). 2015. No. 15 (12). Pp. 29910-29922.
Li J., Ma Y., Xiyuan Ch. Error modeling, calibration, and nonlinear interpolation compensation method of ring laser gyroscope inertial navigation system. Abstract and Applied Analysis. Vol. 2013. Hindawi Publishing Corp., 2013. Pp. 1-7. Article ID 359675.
Liu D.S., Chen Y.W. Application of a new infinite element method for free vibration analysis of thin plate with complicated shapes. In: Computational and experimental simulations in engineering. H. Okada, S. Atluri (eds.). ICCES 2019. Mechanisms and Machine Science. Vol. 75. Springer, Cham. 2020. Pp. 301-306.
Man L., Man E. Electro-thermal analogies for temperature calculation. Proceedings of the 2011 34th International Spring Seminar on Electronics Technology (ISSE). (Tratanska Lomnica, Slovakia, 11-15 May, 2011). IEEE. Pp. 358-362.
Lukyanov D., Filatov Yu., Golyaev Yu. et al. 50th anniversary of the laser gyro. 20th Saint-Petersburg International Conference on Integrated Navigation Systems. ICINS 2013. Pp. 36-49.
Madera A.G. The concept of mathematical and computer simulation of thermal processes in electronic systems. Software Systems. 2015. No. 4 (112). Pp. 79-86.
Miyazaki N., Ikeda T. Application of computational mechanics to reliability studies of electronic packaging. Computational Methods in Engineering and Science (EPMESC X). Aug. 21-23, 2006. Hainan, China. Tsinghua University Press Springer.
Naveen S., Siva Rama Krishna A., Konayya D. et al. Modeling and analysis of monolithic tri-axial ring laser gyro. International Journal of Emerging Technology and Advanced Engineering. 2013. Vol. 3. Issue 9. Pp. 145-148.
Okada H., Liu C., Ninomiya T. et al. Analysis of particulate composite materials using an element overlay technique. CMES: Computer Modeling in Engineering Sciences. 2004. Vol. 6. No. 4. Pp. 333-348.
Raja B., Praveenkumar V., Leelaprasad M., Manigandan P. Thermal simulations of an electronic system using ansys icepak. Int. Journal of Engineering Research and Applications. 2015. Vol. 5. Issue 11 (Part 1). Pp. 57-68.
Shalumov A.S., Kofanov Yu.N., Uvaysov S.U. et al. Automated system ASONIKA for modeling of physical processes in radioelectronic devices with considering of outer influences. Moscow: Radiotekhnika, 2013. 424 p. (In Rus.)
Shafic S.I., Velez G., Toro C. et al. Designing Intelligent Factory: Conceptual Framework and Empirical Validation. ISSE 2017. 40th International Spring Seminar on Electronics Technology. Red Hook, USA: IEEE Computer Society, 2017. Pp. 1801-1808.
Stroganov A., Zhadnov V., Polesskii S. Review of software complexes for reliability calculation of complicated technical systems. Components and Technologies. 2007. No. 5. Pp. 183-190.
Sukhanov V.O., Kukartsev V.V. Actuality of CALS-technologies application at the engineering enterprises of Russia. Actual Problems of Aviation and Cosmonautics. 2011. Vol. 1. No. 7. Pp. 466-467.
Udalov A.I. Thermal designing of radioelectronic devices. Moscow: MIREA, 2007. 211 p. (In Rus.)
Yovanovich M.M. Four decade of research on thermal contact, gap, and joint resistance in mictroelectronics. IEEE Trans. CPMT, 28. 2005. Pp. 182-206.
Keywords:
laser gyroscope, thermal computer modeling, method of electrothermal analogies, method of gradual disaggregation (zooming), finite difference method, grid method, graph method.
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