Search Results for “Morozov O. D.” – Collected book of scientific-technical articles

2.1.2020 Analysis of development trends of design parameters and basic characteristics of missiles for the advanced multiple launch rocket systems

2. Analysis of development trends of design parameters and basic characteristics of missiles for the advanced multiple launch rocket systems

Authors:

Aksenenko A. V.¹, Hurskyi O. I.¹, Klochkov A. S.¹, Kondratiuk Ye. A.¹, Senkin V. S.², Siutkina-Doronina S. V.²

Organization:

Yangel Yuzhnoye State Design Office, Dnipro, Ukraine¹; The Institute of Technical Mechanics, Dnipro, Ukraine²

Page: Kosm. teh. Raket. vooruž. 2020, (1); 13-25

DOI: https://doi.org/10.33136/stma2020.01.013

Language: Russian

Annotation: The scientific and methodological propositions for the designing single-stage guided missiles with the solid rocket motors for advanced multiple launch rocket systems are defined. The guided missiles of multiple launch rocket system are intended for delivering munitions to the given spatial point with required and specified kinematic motion parameters at the end of flight. The aim of the article is an analysis of the development trends of the guided missiles with the solid rocket motors for the multiple launch rocket systems, identifying the characteristics and requirements for the flight trajectories, design parameters, control programs, overall dimensions and mass characteristics, structural layout and aerodynamic schemes of missiles. The formalization of the complex task to optimize design parameters, trajectory parameters and motion control programs for the guided missiles capable of flying along the ballistic, aeroballistic or combined trajectories is given. The complex task belongs to a problem of the optimal control theory with limitations in form of equa lity, inequality and differential constraints. To simplify the problem, an approach to program forming is proposed for motion control in the form of polynomial that brings the problem of the optimal control theory to a simpler problem of nonlinear mathematical programming. When trajectory parameters were calculated the missile was regarded as a material point of variable mass and the combined equations for center-of-mass motion of the guided missile with projections on axes of the terrestrial reference system were used. The structure of the mathematical model was given along with the calculation sequence of the criterion function that was used for determination of the optimal parameters, programs and characteristics. The mathematical model of the guided missile provides adequate accuracy for design study to determine depending on the main design parameters: overall dimensions and mass characteristics of the guided missile in general and its structural comp onents and subsystems; power, thrust and consumption characteristics of the rocket motor; aerodynamic and ballistic characteristics of the guided missile. The developed methodology was tested by determining design and trajectory parameters, overall dimensions and mass characteristics, power and ballistic characteristics of two guided missiles with wings for advanced multiple launch rocket systems produced by the People’s Republic of China, using the limited amount of information available in the product catalog.

Key words: multiple launch rocket systems (MLRS), complex problem of the optimal control theory, problem of nonlinear mathematical programming, main solid rocket motor, limitations for motion parameters and basic characteristics of the guided missiles

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22. Aksenenko A. V., Baranov E. Yu., Hursky A. I., Klochkov A. S., Morozov A. S., Alpatov A. P., Senkin V. S., Siutkina-Doronina S. V. Metodicheskoe obespechenie dlia optimizatsii na nachalnom etape proektirovaniia proektnykh parametrov, parametrov traektorii i programm upravleniia dvizheniem raketnogo ob’ekta. Kosmicheskaia tekhnika. Raketnoe vooruzhenie: sb. nauch.-tekhn. st. / GP “KB “Yuzhnoye”. Dnipro, 2018. Vyp. 2 (116). S. 101–116. https://doi.org/10.33136/stma2018.02.101

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5.1.2020 Strength and stability of inhomogeneous structures of space technology, consid-ering plasticity and creep

Wed, 13 Sep 2023 06:15:53 +0000

5. Strength and stability of inhomogeneous structures of space technology, consid-ering plasticity and creep

Authors:

Hudramovych V. S.², Sirenko V. M.¹, Klimenko D. V.¹, Hart Ye. L.³

Organization:

Yangel Yuzhnoye State Design Office, Dnipro, Ukraine¹; The Institute of Technical Mechanics, Dnipro, Ukraine²; Oles Honchar Dnipro National University, Dnipro, Ukraine³

Page: Kosm. teh. Raket. vooruž. 2020, (1); 44-56

DOI: https://doi.org/10.33136/stma2020.01.044

Language: Russian

Annotation: The shell structures widely used in space rocket hardware feature, along with decided advantage in the form of optimal combination of mass and strength, inhomogeneities of different nature: structural (different thicknesses, availability of reinforcements, cuts-holes et al.) and technological (presence of defects arising in manufacturing process or during storage, transportation and unforseen thermomechanical effects). The above factors are concentrators of stress and strain state and can lead to early destruction of structural elements. Their different parts are deformed according to their program and are characterized by different levels of stress and strain state. Taking into consideration plasticity and creeping of material, to determine stress and strain state, the approach is effective where the calculation is divided into phases; in each phase the parameters are entered that characterize the deformations of plasticity and creeping: additional loads in the equations of equilibrium or in boundary conditions, additional deformations or variable parameters of elasticity (elasticity modulus and Poisson ratio). Then the schemes of successive approximations are constructed: in each phase, the problem of elasticity theory is solved with entering of the above parameters. The problems of determining the lifetime of space launch vehicles and launching facilities should be noted separately, as it is connected with damages that arise at alternating-sign thermomechanical loads of high intensity. The main approach in lifetime determination is one that is based on the theory of low-cycle and high-cycle fatigue. Plasticity and creeping of material are the fundamental factors in lifetime substantiation. The article deals with various aspects of solving the problem of strength and stability of space rocket objects with consideration for the impact of plasticity and creeping deformations.

Key words: shell structures, stress and strain state, structural and technological inhomogeneity, thermomechanical loads, low-cycle and high-cycle fatigue, lifetime

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13.1.2018 On Selection of Materials for Creation of Modern LV Thermostating System Mating Hoses

Tue, 05 Sep 2023 06:52:56 +0000

13. On Selection of Materials for Creation of Modern LV Thermostating System Mating Hoses

Authors:

Bigun S. O.¹, Yevchik V. S.², Khorolskyi M. S.²

Organization:

Yangel Yuzhnoye State Design Office, Dnipro, Ukraine¹; State Enterprise DINTEM Ukrainian Research Design-Technological Institute of Elastomer Materials and Products²

Page: Kosm. teh. Raket. vooruž. 2018 (1); 72-84

DOI: https://doi.org/10.33136/stma2018.01.072

Language: Russian

Annotation: A series of materials is proposed for creation of space launch vehicle low-pressure air thermostating systems joints hoses. The topical issues are considered of materials designing with consideration for specific features of the hoses as special industrial rubber articles of launch vehicle launch sites.

Key words:

Bibliography:

1. Raw Stuff and Materials: Inf. Bull. М., 1999. No. 1. 44 p. https://doi.org/10.1007/978-1-4615-2802-9_3

2. Svitlichna R. F., Lotakov V. S., Chumicheva N. P. State and Prospects of Using Rubbers of New Generation in Rubber Industry of Ukraine: Scientific-Technical Report. К., 2001. No. 3. 13 p.

3. Nesterova L. A., Reznichenko S. V., Noskova L. F. et al. Experience of Using BNKS Paraffinate Nitrile Rubber in Formulations of Oil-Resistant Rubbers of Various Purpose at JSC “Uralsky Zavod RTI”. Med. Conf. on rubber: Collection of abstracts. М., 2000. No. 4. 121 p.

4. Investigation to Select Optimal Options of Replacing Raw Materials and Rubbers with Specifying Guaranteed Service and Storage Life of Rubber Products Being Components of Special Articles: Scientific–Technical Report DO-473-2002 UNUKTI DINTEM SE. 2002. 47 p.

5. Raw Stuff and Materials: Inf. Bull. М., 1999. No. 5. 55 p.

6. Raw Stuff and Materials: Inf. Bull. М., 2001. No. 3. 90 p.

7. Raw Stuff and Materials: Inf. Bull. М., 2001. No. 3. 96 p.

8. Raw Stuff and Materials: Inf. Bull. М., 2000. No. 3. 43 p.

9. Lotakov V. S., Yevchik V. S., Utlenko E. V. et al. Investigation of Operability of Rubbers with Adhesion Additives in Rubber-Metal Valves. Manufacture of Tires, Rubber Products and ATI. М., 1980. No. 4. P. 43-44.

10. Lotakov V. S., Yevchik V. S., Markova L. A. et al. Investigation of Alkali Impact on Adhesive Properties of Ethylene-Propylene Vulcanizing Agents. Caoutchouc and Rubber: Scientific–Technical Report. UNIKTI-DINTEM SE. 1981. No. 6. P. 18-19.

11. Svitlichna R. F., Bogutska E. O., Lotaakov V. S. et al. Technical Carbon of N Series. Prospects of Using in Rubber Mixtures of Caoutchoucs of New Generation: Scientific–Technical Report. К., 2006. No. 3. P. 17-20.

12. Yevchik V. S., Bogutskaya E. A., Khorolsky M. S. Investigations to Select Optimal Options of Replacing Raw Materials and Rubbers with Specifying Guaranteed Service and Storage Life of Rubber Products Being Components of 11K77 Article: Scientific–Technical Report DO-468-2000, UNIKTI-DINTEM SE. 2000. 55 p.

13. Nudelman Z. N., Lavrova L. N. Effective Vulcanization of Fluorine Rubbers. The III Ukr. International Scientific-Technical Conference of Rubber Industry Workers: Collection of abstracts. Dnepropetrovsk, 2000. 43 p.

14. Semyonov G. D., Yevchik V. S., Zaitseva T. P., Lotakov V. S. Prospects of Using New Vulcanizing Systems in Rubber Mixtures Based on Fluoroelastomers: Scientific–Technical Report. К., 2001. No. 3. 18 p.

15. Yevchik V. S., Zaitseva T. P., Khorolsky M. S. Investigations of Physical-Mechanical Characteristics of Rubbers Based on Caoutchoucs of New Generation: Scientific–Technical Report DO-387-89, DF VNIIEMI. Dnepropetrovsk, 2000. 61 p.

16. Belozerov N. V. Rubber Technology. М., 1979. 201 p.

17. Blokh G. A. Organic Rubber Vulcanization Accelerators. М.,1964. 156 p.

18. Big Reference Book of Rubber Industry Worker in 2 parts. Part 1. Rubbers and Ingredients / Under the general editorship of S. V. Reznichenko and Y. L. Morozov. М., 2012. 740 p.

19. Polyurethane Chemistry and Technology: Collection of conference papers. Manchester, 1967. 254 p.

20. Degteva T. G. et al. The Impact of Additives on Thermal Ageing of Rubbers and Model Gaskets Made of SKEP. Caoutchouc and Rubber. М., 1984. No. 8. P. 17-19.

21. Lepetov V. A. Rubber Products. L., 1976. 440 p.

22. Lepetov V. A., Yurtsev L. N. Calculations and Designing of Rubber Products and Production Accessories. М., 2009. 417 p.

23. New Prospective Hoses and Scarce and Commercially Inviable Rubbers, Ingredients and Materials: Recommendation No. 51-РМ-22/38/57/50-1050-83. М., 1983. 42 p.

24. Kornev A. E. et al. Technology of Elastomer Materials. М., 2009. 504 p.

25. Gerasimenko A. А. Protection of Machines from Biological Damages. M., 1984. 92 p.

26. Principles of Constructing Formulations and Using Rubbers for Rubber Products of Tropical Version: Recommendation No. 51-РМ-26-48-66. М., 1966. 56 p.

27. Assessment of Rubber Resistance to Damage by Thermites: Recommendation No. 51-РМ-4-622-75. М., 1975. 36 p.

28. Increasing Rubber Products Service Life in Conditions of Tropical Climate: Recommendation No. 51-РМ-4-697-76. М., 1976. 23 p.

29. Assessment of Rubber Resistance to Mould: Recommendation No. 51-РМ-4-407-73. М., 1976. 42 p.

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25.2.2017 Vacuum Conditions Simulation Criteria

Wed, 09 Aug 2023 12:46:44 +0000

25. Vacuum Conditions Simulation Criteria

Authors:

Logvinenko A. I.

Organization:

Yangel Yuzhnoye State Design Office, Dnipro, Ukraine

Page: Kosm. teh. Raket. vooruž. 2017 (2); 141-145

Language: Russian

Annotation: The paper shows the peculiarities of modeling the vacuum conditions to simulate space environment when conducting various test types. Based on generalized experience, the practical criteria are recommended with consideration for accompanying physical phenomina.

Key words:

Bibliography:

1. Rozanov L. N. Vacuum Engineering. М., 1990. 320 p.

2. Polukhin D. A., Oreshchenko V. M., Morozov V. A. Testing of Pneumohydraulic Subsystems of Propulsion Systems of LV and SC with LRE. М., 1987.

3. Deshman S. Scientific Basis of Vacuum Engineering. М., 1970.

4. Borisenko A. I. Gas Dynamics of Engines. М., 1962. 793 p.

5. Avduyevsky V. S. Fundamentals of Heat Transfer in Aerospace Engineering. М., 1975. 623 p.

6. Burdakov V. P., Danilov Y. I. External Resources and Cosmonautics. М., 1976. 551 p.

7. Kuda S. A. et al. Investigation of Freezing Conditions of Liquid Nitrogen in Manifolds at Flowing into Vacuum / S. A. Kuda, Zh. V. Kabakova, A. I. Logvinenko, V. I. Porubaimekh. Space Technology. Missile Armaments: Collection of scientific-technical articles. 2007. Issue 2. P. 58 – 67.

8. Patent 110307 Ukraine, MPK F25J 1/00. Method of Producing Overcooled Cryogenic Liquid / D. I. Gudymenko, S. A. Kuda, А. I. Logvinenko, V. I. Porubaimekh (Ukraine); Applicant and patent holder Yuzhnoye SDO. No 201601457; Claimed 18.02.2016; Published 10.10.2016, Bulletin No. 19.

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22.1.2019 Calculation of Uncertainty of Represented Values of Linear Accelerations during Centrifugal Machines Certification

Wed, 24 May 2023 16:00:54 +0000

22. Calculation of Uncertainty of Represented Values of Linear Accelerations during Centrifugal Machines Certification

Authors:

Bondar’ М. А., Voloshina M. O., Yeres L. O., Kurako I. М., Morozov O. D.

Organization:

Yangel Yuzhnoye State Design Office, Dnipro, Ukraine

Page: Kosm. teh. Raket. vooruž. 2019, (1); 149-153

DOI: https://doi.org/10.33136/stma2019.01.149

Language: Russian

Annotation: Applicable documents on metrological assurance regulate the estimation of measurement uncertainty. In Ukraine there is no regulative methodology for uncertainty calculation when certificating test equipment that causes the necessity of its definition. This article offers the methodology for uncertainty calculation when certificating a centrifugal machine that is used to reproduce precisely the given value of linear acceleration that permanently acts on a tested unit spinning together with a rotor. The offered methodology for uncertainty calculation is applicable to centrifugal machines, for which numerical values of reproducible linear acceleration are determined by results of calculations of the centrifugal machine’s rotor angular velocity and radial distance from rotor’s longitudinal axis to the given point of the tested unit. Initial data used were results of observation obtained after multiple reproductions of the given values of linear acceleration as well as numerical values of errors and measurement uncertainties of measuring equipment that was used when monitoring the rotary angular velocity and radial distance considering the contribution of each measurable parameter to a certain value of linear acceleration. The calculation given in the article estimates the limit of linear accelerations that can be attributed with established probability to the given value of linear acceleration reproduced when certificating the centrifugal machine. The design formulae are given to estimate the uncertainty components of the reproducible values of linear accelerations and the recommendations are given to present the uncertainty budget.

Key words: extended uncertainty, standard uncertainty, sensitivity coefficient, measurement uncertainty contribution, frequency meter

Bibliography:

1. GOST 24555. Poryadok attestatsii ispytatelnogo oborudovania. Osnovnye polozheniya. Vved. 27.01.81. M.: Gosstandart, 1982. 12 p.

2. https://www.twirpx.com/file/1791976.

3. Guide to the Expression of Uncertainty in Measurement: ISO. Geneva, 1993. 101 p.

4. Zakon Ukrainy «Pro metrologiu ta metrologychnu diyalnist’»// Vidom. Verkhovnoi Rady (VVR). 2014. № 30. P.1008.

5. Duplischeva O. M. i dr. Experimentalnaya otrabotka agregatov avtomatiki I system letatelnykh apparatov/ Pod obsch. red. d. t. n. A. V. Degtyareva. Dnepropetrovsk: GP KB «Yuzhnoye» im. M. K. Yangelya», 2013. 208 p.

6. Bondar’ M. A. i dr. Metodologia otsenivania neopredelennosti izmerenniy pri provedenii attestatsii sredstv izmeritelnoi techniki//Kosmicheskaya technika. Raketnoe vooruzhenie: Sb. nauch. – techn. st. 2017. Vyp. 1. P. 3–7.

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7.1.2023 Specificity of using rubbers as structural materials for making connector assemblies of temperature conditioning systems

Fri, 12 May 2023 16:10:58 +0000

7. Specificity of using rubbers as structural materials for making connector assemblies of temperature conditioning systems

Authors:

Khorolskyi M. S.², Bigun S. O.¹

Organization:

Yangel Yuzhnoye State Design Office, Dnipro, Ukraine¹; State Enterprise DINTEM Ukrainian Research Design-Technological Institute of Elastomer Materials and Products²

Page: Kosm. teh. Raket. vooruž. 2023 (1); 63-69

DOI: https://doi.org/10.33136/stma2023.01.063

Language: Ukrainian

Annotation: Explosive bolts are widely used as actuating devices in the spacecraft separation systems. Explosive bolt body is divided into parts as a result of engagement of the pyromixture placed inside. Activated explosive bolts have negative mechanical effect on the interface elements and sensitive electronic devices installed nearby owing to explosive behavior of the pyromixture combustion, generating shock front with high pressure and velocities, impacts and collisions of the structural units. Cumulative effect of the above factors on the separated objects is called pyroshock. For separation systems with increased requirements to external actions and cleanliness, authors developed a shear explosive bolt or pyrobolt, divided into parts, cutting the body walls in segments, which are set in motion by action of the pressure of gases, released as a result of pyrocartridge activation. The basic sources of pyroshock for these shear explosive bolts with segments are: combustion of pyromixture, internal impacts of structural units against the bolt body; cutting of body wall in segments, release of preliminary deformed interface after activation. Structural solutions are presented to reduce the pyroshock per each of the components. Vibration impulsive loading during pyromixture combustion is reduced by optimization of explosive quantity, finding its minimum to provide the reliable activation of the device. To reduce the impact on the explosive bolt elements and shock front interface the rubber gasket is installed in the path of shock wave distribution, partially disseminating and absorbing its kinetic energy. Damper, made of easily deformable aluminum alloy, is also installed to decrease the internal impact of the rod against the explosive bolt body. Functional testing of the device, using the pendulum suspension and measuring separation speed and vibration impulsive loading, showed that body parts of the shear explosive bolt with segments are separated without significant impact loads and discharge of high-temperature gases and debris, providing reliable separation of compartments and units without damaging the sensitive equipment. Obtained values of the mechanical momentum, I = 0,4÷0,7 N•s and shock load spectrum – g-load 1950 g at the frequency range up to 5000 Hz, meet the up-to-date requirements to pyrotechnical devices.

Key words: explosive bolt, pyroshock, shock wave, pyrocartridge, high-temperature gases, damper

Bibliography:

1. Bigun S. A., Khorolskiy M. S. i dr. Tipy i konstruktivnye osobennosti uzlov stykovki system termostatirovania golovnyh blokov i otsekov raket-nositeley kosmicheskyh apparatov. Kosmicheskaya technika. Raketnoe vooruzhenie: sb. nauch.-techn. st. GP «KB «Yuzhnoye». Dnepropetrovsk, 2013. Vyp. 1. S. 65-68.

2. Bigun S. A., Khorolskiy M. S. Problemnye voprosy sozdania uzlov stykovki system termostatirovania raket kosmicheskogo naznachenia. Kosmicheskaya technika. Raketnoe vooruzhenie. Space technology Missile armaments: sb. nauch.-techn. st. GP «KB «Yuzhnoye». Dnepropetrovsk, 2013. Vyp. 2. S. 132-138.
3. Pat. Frantsii №2658479 (А2), 1991, MPK kl. В64G 1/40; В64G 1/64, В64G 5/00.
4. Pat. Frantsii №2685903 (А1), 1993, MPK kl В64G 5/00; F41F3/055; F02K9/44.
5. Pat. Rossiyskoi Federatsii №2473003-S1, 2011 r., MPK7F16L 37/20.
6. Yrtsev L. N., Bukhin B. L. Rezina kak konstruktsionniy material. Bolshoy spravochnik rezinschika. V dvuh chastyah. Ch. 1. Kauchuki i ingredienty. Pod red. S. V. Reznichenko, Yu. L. Morozova. M., 2012. 744 s.
7. GOST 263-75. Rezina. Metod opredelenia tverdosti po Shoru A (s izmeneniyami № 1, 2, 3, 4). M., 1989. 10 s.
8. Koshelev F. F., Kornev A. Ye., Bukanov A. M. Obschaya technologia reziny. Izd. 4-e, pererab. i dop. M., 1978. 528 s.
9. Skokov A. I., Kaplun S. V., Bogutskaya Ye. A., Khorolskiy M. S., Bigun S. A. Technologicheskie aspekty sozdaniya rukavov stykovki system termostatirovania raket-nositeley. Kosmicheskaya technika. Raketnoe vooruzhenie: sb. nauch.-techn. st. GP «KB «Yuzhnoye». Dnepropetrovsk, 2015. Vyp. 1. S. 42-45.
10. Bigun S. A., Yevchik V. S., Khorolskiy M. S. O vybore materialov dlya sozdaniya rukavov stykovki system termostatirovania sovremennyh RKN. Kosmicheskaya technika. Raketnoe vooruzhenie. Space technology Missile armaments: sb. nauch.-techn. st. GP «KB «Yuzhnoye». Dnepr, 2018. Vyp. 1. S. 72-84. https://doi.org/10.33136/stma2018.01.072
11. Pat. Ukrainy № 120445, 2019 r., В64G 5/00, В64G 1/40, F16L 37/08, F41F 3/055, F16L 33/00.
12. Pat. Ukrainy № 120469, 2019 r., В64G 5/00, В64G 1/40, F25B 29/00, F16L 33/00,F16L 37/12, F16L 25/00.
13. Khorolskiy M. S., Bigun S. O. Shodo kontseptsii stvorennya vuzliv stykuvannya system termostatuvannya raket kosmichnogo pryznachennya. Systemne proektuvannya i analiz characteristic aerokosmichnoi techniki: zb. nauk. pr. 2019. T. XXVII. S. 162-168.
14. Bigun S. A., Khorolskiy M. S. i dr. Eksperimentalnye issledovania rezultatov otrabotki uzlov stykovki system termostatirovania RKN «Tsiklon-4». Kosmicheskaya technika. Raketnoe vooruzhenie: sb. nauch.-techn. st./ GP «KB «Yuzhnoye». Dnepropetrovsk, 2016. Vyp. 2. S. 43-51.

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1.1.2023 On the development of a methodology for building air and missile defense systems. Explanation of the investigation mechanism

Thu, 11 May 2023 15:25:30 +0000

1. On the development of a methodology for building air and missile defense systems. Explanation of the investigation mechanism

Authors:

Perkov V. M., Herasimov A. P., Degtyarev O. V.

Organization:

Yangel Yuzhnoye State Design Office, Dnipro, Ukraine

Page: Kosm. teh. Raket. vooruž. 2023 (1); 3-13

DOI: https://doi.org/10.33136/stma2023.01.003

Language: Ukrainian

Annotation: Substantiation of the research tools has been performed as a part of methodology development for the air and missile defense system. The problem under consideration is very complex due to the multifactorial nature of the research object, its qualitative variety and manifold structure, incomplete definition of the problem statement. Furthermore, the ability of modern technologies to produce different arms systems, which are capable of carrying out same class tasks, considerably increases the risk of making not the best decisions. Based on this, as well as taking into account the sharp increase in the cost of weaponry, the considered problem is classified as an optimization one that should be solved through the theory of operations research. In this theory, such task is viewed as a mathematical problem, and mathematical simulation is the basic method of research. The main types of mathematical models, their areas of application have been considered as a part of the analysis. The classification of mathematical models has been indicated according to the scale of reproduced operations, purpose, and goal orientation. Quantitative and qualitative correlation of forces has been accepted as the efficiency criterion, which determines a goal orientation of the model. The problems related to this have been shown. In particular, searching for the compromise between simplicity of the mathematical model and its adequacy to the research object is among these problems. Two of the basic approaches to principles of the military operation model construction and its assessment have been considered. The first is implemented through modeling of the combat operations. The second approach is based on the assumption that different armament types can be compared based on their contribution to the outcome of the operation, and on the possibility to assign «a weighting coefficient» named as a combat potential to each of these types. The modern level of problem solving related to this method has been shown. The reasonability of its application in the considered task, including the definition of forces correlation of the opposing parties, has been substantiated. The basic regulations of the construction concept of the required mathematical model and tools for its research have been formulated based on the analysis results: the assigned problem should be solved by analytical methods through the theory of operations research; the analytical model is the most acceptable conception of the analyzed level of the military operation; the synthesis of the model should be based on the idea of a combat potential. At the same time, it should be taken into account that the known approach to the definition of forces correlation, which uses the combat potential method, has a number of essential limitations, including the methodological ones. Therefore, within the bounds of further research, this approach requires the development both in terms of improving the reliability of the single assessment and in terms of giving the system qualities to the synthesized mathematical model.

Key words: multifunctional system, mathematical model, military unit, combat potential, correlation of forces, defensive sufficiency

Bibliography:

Korshunov Yu. M. Matematicheskie osnovy kibernetiki. M., 1972. 376 s.
Pavlovskiy R. I., Karyakin V. V. Ob opyte primeneniya matematicheskih modeley. Voennaya mysl. № 3. S. 54-57.
Katasonov Yu. V. SShA: voennoe programmirovanie. M., 1972. 228 s.
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Sokolov A. Razvitie matemaicheskogo modelirovaniya boevyh deistviy v armii SShA. Zarubezhnoye voennoe obozrenie. № 8. S. 27-34.
Chuev Yu. V. Issledovanie operatsiy v voennom dele. M., 1970. 256 s.
Yevstigneev V. N. K voprosu metodologii matematicheskogo modelirovaniya operatsii. Voennaya mysl. № 17. S. 33-41.
Fendrikov I., Yakovlev V. I. Metody raschetov boevoy effectivnosti vooruzhennia. M., 1971. 224 s.
Neupukoev F. O podhode k otsenke boevyh vozmozhnostey i boevoy effectivnosti voisk. Voennaya mysl. № 11. S. 70-72.
AgeevYu. D., Geraskin A. P. K voprosu o povyshenii dostovernosti otsenki sootnosheniya sil protivoborstvuyuschih storon. Voennaya mysl. № 4. S. 54-58.
Aleshkin A. V. Otsenka i soozmerenie sil voyuuschih storon s uchetom kachestva sredstv porazhenya. Voennaya mysl. № 10. S. 69-76
Ponomarev O. K. O metodah kolichestvennoy i kachestvennoy otsenki sil storon. Voennaya mysl. № 4. S. 41-46.
Luzyanin V. P., Elizarov V. S. Podhod k opredeleniyu sostava gruppirovki sil i sredstv oboronnoy dostatochnosti. Voennaya mysl. № 11. S. 25-29.
SpeshilovL. Ya., Pavlovskiy R. I., Kabysh A. I. K voprosu o kolichestvenno-kachestvennoy otsenke sootnosheniya sil raznorodnyh gruppirovok voisk. Voennaya mysl. № 5.
. Strelchenko B. I., Ivanov V. A. Nekotoye voprosy otsenki sootnosheniya sil i sredstv v operatsii. Voennaya mysl. № 10. S. 55-61.
Morozov N. A. O metodologii kachestvennogo analiza bolshih voennyh system. Voennaya mysl. № 7. S. 19-22.
Terehov A. G. O metodike rascheta sootnosheniya sil v operatsii. Voennaya mysl. № 9. S. 51-57.
Tsygichko V. A., Stokli F. Metod boevyh potentsialov. Istoria i nastoyaschee. Voennaya mysl. № 4. S. 23-28.
BoninA. S. Osnovnye polozheniya metodicheskyh podhodov k otsenke boevyh potentsialov i boevyh vozmozhnostey aviatsionnyh formirovaniy. Voennaya mysl. № 1. S. 43-47.
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Ostankov V. I. Obosnovanie boevogo sostava gruppirovok voisk (sil). Voennaya mysl. № 1. S. 23-28.

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