Choice and adaptation of agrotechnologies

Methodological rationale for the research is the acknowledgement of the fact that the nature of things is located in the complex informational space characterized by diversity, complexity and uncertainty. The paper presents the study into the automated choice of agrotechnologies conducted in Russia. It is shown that deterministic approach on the basis of the regressive models and the account of the average resource changeability prevails in the part of work related to the creation of the software on automated (computerized) choice of agrotechnologies. The task of operational control of agro-approaches during implementation of agrotechnologies is not set in this work: only partial adaption is carried out. Agrotechnologies are implemented in the system “human being -piece of machinery - plant”, whereby “plant” is an independent, actively operating agent, so the whole system is probabilistic (stochastic). This statement gives reason to consider that deterministic approach based on the regressive models does not meet current requirements and does not implement agrotechnological adaptation to the full extent. One of the options of solving this problem is imitational modelling which involves implementation of the dynamic approach. The present capacity level of computers and software removes technical limitations. Requirements to conceptualizing of the subject area, the choice of models for knowledge presentation and the framework of their implementation are placed in the forefront. With the development of digital technologies in agriculture, new opportunities arise for obtaining extra informational resources necessary to be effectively applied in the process of development and implementation of managerial decisions. The significant change in the structure and content of informational service of agriculture and a wider application of intellectual analysis are expected.

1. Eitzinger A., Lдderach P., Rodriguez B., Fisher M., Beebe S., Sonder K., Schmidt A. Assessing highimpact spots of climate change: spatial yield simulations with Decision Support System. Mitigation and Adaptation Strategies for Global Change, 2017, vol. 22, no. 5, pp. 743-760. ( DOI: 10.1007/s11027-015-9696-2).

2. Fry J., Guber A.K., Ladoni M., Munoz J.D., Kravchenko A.N. The effect of up-scaling soil properties and model parameters on predictive accuracy of DSSAT crop simulation model under variable weather conditions. Geoderma, 2017, vol. 287, pp. 105-115. DOI: 10.1016/j.geoderma.2016.08.012.

3. Anderson R., Keshwani D., Guru A., Yang H., Irmak S., Subbiah J. An integrated modeling framework for crop and biofuel systems using the DSSAT and GREET models. Environmental Modelling & Software, 2018, vol. 108, pp. 4050. DOI: 10.1016/j.envsoft.2018.07.004.

4. De Wit A., Boogaard H., Fumagalli D., Janssen S., Knapen R., van Kraalingen D., Supit I., van der Wijngaart R., van Diepen K. 25 years of the WOFOST cropping systems model // Agricultural Systems, 2019,vol. 168, pp. 154-167. DOI: 10.1016/j.agsy.2018.06.018.

5. Tyupakov K.E. Osobennosti effektivnogo formirovaniya i vosproizvodstva tekhniko-tekh-nologicheskoi bazy rastenievodstva [Features of effective formation and reproduction of the technical and technological base of crop science]. Krasnodar: Izdatel’stvo Kubanskogo gosudarstvennogo universiteta [Printing house of Kuban State University], 2016, 274 p. (In Russian).

6. Krutova I.N., Klimenko A.S., Shvedova M.V. Analiz rentabel’nosti i strategii razvitiya sel’skogo khozyaistva Rossii [Analysis of profitability and development strategy of agriculture of Russia]. Sistemnoe upravlenie [System management], 2011, no. 4, pp. 1-10. (In Russian).

7. Altukhov A.I. Osnovnye problemy razvitiya APK i puti ikh resheniya [The main problems of AIC development and ways of their solution]. Vestnik Kurskoi GSKhA [Vestnik of Kursk State Agricultural Academy], 2014, no. 2, pp. 2-6. (In Russian).

8. Morozyuk Yu.V., Gorbatenko A.P. Sel’skokhozyaistvennye predpriyatiya na sovremen-nom etape razvitiya ekonomiki Rossiiskoi Federatsii [Agricultural enterprises on the present stage of development of the Russian economy]. TDR [Transport business of Russia], 2014, no. 2, pp. 3-4. Russian).

9. Polukhin A.A. Tekhnicheskaya modernizatsiya sel’skogo khozyaistva Rossii v usloviyakh mezhdunarodnoi integratsii i ekonomicheskikh sanktsii [Technical modernization of agriculture of Russia under conditions of international integration and economic sanctions]. RJOAS [Russian Journal of Agricultural and SocioEconomic Sciences], 2015, no. 6, pp. 41-51. (In Russian).

10. Vorozheikina T.M. Osobennosti konkurentsii v sel’skom khozyaistve [Features of competition in agriculture]. Ekonomika sel ’skokhozyaistvennykh i pererabatyvayushchikh predpriyatii [Economy of agricultural and processing enterprises], 2012, no. 2, pp. 12-15. (In Russian).

11. Kaneman D., Slovik P., Tverski A. Prinyatie reshenii v neopredelennosti: pravila i predu-bezhdeniya [Decisionmaking in uncertainty: rules and prejudices]. Khar’kov: Izdatel’stvo Instituta prikladnoi psikhologii «Gumanitarnyi Tsentr» [Publishing house of the Institute of Applied Psychology “Humanitarian center”], 2005, 632 p. (In Russian).

12. Filosofskii slovaf [Dictionary of Philosophy], pod red. I.T. Frolova. 7 izd.-e, pererab. i dop. M., Respublika Publ., 2001, 719 p. (In Russian).

13. Ozhegov S.I., Shvedova N.Yu. Tolkovyi slovar ’ russkogo yazyka [Definition dictionary of the Russian language], 4-e izd., dop. M., OOO «A TEMP» Publ., 2006. 944 p. (In Russian).

14. Rastrigin L.A. Adaptatsiya slozhnykh system [Adaptation of complex systems], Riga, Zi-natne Publ., 1981, 375 p. (In Russian).

15. Eshbi U.R. Vvedenie v kibernetiku [Introduction into cybernetics], / pod red. V.A. Uspen-skogo. M., Izdatel’stvo inostrannoi literatury [Printing house of Foreign Literature], 1959, 428 p. (In Russian).

16. Lutsenko E.V. Modelirovanie slozhnykh mnogofaktornykh nelineinykh ob”ektov upravleniya na osnove fragmentirovannykh zashumlennykh empiricheskikh dannykh bol’shoi razmernosti v sistemno-kognitivnom analize i intellektual’noi sisteme «EIDOS-Kh++» [Modelling of complex multifactor nonlinear control objects based on a fragmented noisy empirical high-dimensional data in a system cognitive analysis and in the intellectual EIDOS-Kh++ system]. Nauchnyi zhurnal Kubanskogo gosudarstven-nogo agrarnogo universiteta [Scientific Journal of Kuban State Agrarian University], 2013, no. 91 (07), pp. 1-25. (In Russian).

17. Gostev A.V. Avtomatizirovannye programmy vybora tekhnologii vozdelyvaniya yarovykh i ozimykh zernovykh kul’tur v TsChR [Automated software for choosing grain crop cultivation technology in Central-chernozem region]. Zemledelie [Zemledelie], 2013, no. 1, pp. 8-11. (In Russian).

18. Pykhtin I.G., Gostev A.V., Pykhtin A.I. Sovershenstvovanie sistem zemledeliya i agrotekhnologii v sovremennykh usloviyakh vedeniya sel’skogo khozyaistva [Improving of farming conditions and agrotechnologies in the conditions of modern agriculture]. Dostizheniya nauki i tekhniki APK [Achievements of Science and Technology of AIC], 2014, no. 4, pp. 7980. (In Russian).

19. Tiranova L.V., Tiranov A.B. Bazy dannykh dlya razrabotki tekhnologii vozdelyvaniya yarovykh zernovykh kul’tur v usloviyakh Novgorodskoi oblasti [Database for development of spring grain crop cultivation technologies in the conditions of Novgorod region]. Nikonovskie chteniya [Nikonovskie chteniya], 2015, no. 20-1 (20), pp. 229-232. (In Russian).

20. Tiranova L.V., Tiranov A.B. Bazy dannykh dlya razrabotki tekhnologii vozdelyvaniya zer-nobobovykh kul’tur v usloviyakh Novgorodskoi oblasti [Database for development of leguminous crop cultivation technologies in the conditions of Novgorod region]. Nikonovskie chteniya [Nikonovskie chteniya], 2016, no. 21, pp. 222-225. (In Russian).

21. Stepnykh N.V., Zargaryan A.M., Zhukova O.A. Komp’yuternaya programma po proektirovaniyu tekhnologii vyrashchivaniya sel’khozkul’tur [Software for designing crop cultivation technology]. Agrarnyi vestnik Urala [Agrarian Bulletin ofthe Urals], 2017, no. 3 (157), pp. 54-58. (In Russian).

22. Stepnykh N.V., Zhukova O.A., Zargaryan A.M. Razrabotka bazy dannykh tipovykh tekhkart dlya informatsionno-analiticheskogo kompleksa po zemledeliyu [Development of a database of standard task list for informational and analytical complex for agriculture]. Vestnik NGIEI [Herald NGIEI], 2018, no. 4 (83), pp. 5-15. (In Russian).

23. Lutsenko E.V., Loiko V.I., Velikanova L.O. Prognozirovanie i prinyatie reshenii v ras-tenievodstve s primeneniem tekhnologii iskusstvennogo intellekta [Forecasting and decision making on the choice of agricultural technologies in grain production using artificial intelligence]. Krasnodar, Izdatel’stvo Kubansk-ogo gosudarstvennogo agrarnogo universiteta [Printing house of Kuban State Agrarian University], 2008, 257 p. (In Russian).

24. Gorpinchenko K.N., Lutsenko E.V. Prognozirovanie i prinyatie reshenii po vyboru agrotekhnologii v zernovom proizvodstve s primeneniem metodov iskusstvennogo intellek-ta (na primere SK-analiza) [Forecasting and decision making on the choice of agricultural technologies in grain production using artificial intelligence (for example, the SC-analysis). Krasnodar, Izdatel’stvo Kubanskogo gosudarstvennogo agrarnogo universiteta [Printing house of Kuban State Agrarian University], 2013, 168 p. (In Russian).

25. Poluektov R.A. Dinamicheskie modeli agroeko-sistemy [Dynamic models agro-ecological system]. L., Gidrometeoizdat [Hydro-meteorological press], 1991, 312 p. (In Russian).

26. Poluektov R.A., Smolyar E.I., Terleev V.V., Topazh A.G. Modeli produktsionnogo protsessa sel’skokhozyaistvennykh kul’tur [Models of production process of grain crops: monograph]. St. Peterburg, Izdatel’stvo Sankt-Peterburgsk-ogo universiteta [Printing house of St.-Peters-burg University], 2006, 396 p. (In Russian).

27. Poluektov R.A., Topazh A.G., Kobylyanskii S.G. Avtomatizatsiya komp’yuternogo eksperimenta s matematicheskimi modelyami [Automating computer experiment with mathematical models]. Dostizheniya nauki i tekhniki APK [Achievements of Science and Technology of AIC], 2011, no. 2, pp. 61-63. (In Russian).

28. Topazh A.G., Medvedev S.A., Zakharova E.T. Proaktivnoe upravlenie v komp’yuternykh sistemakh podderzhki agrotekhnologicheskikh reshenii na primere upravleniya azotnymi podkormkami [Proactive control in computer support systems of agro-technological decisions on the example of nitrogen dressing control]. AgroEkoInfo [AgroEcoInfo], 2016, no. 4, pp. 12-27. (In Russian).

29. Poluektov R.A., Topazh A.G., Yakushev V.P., Medvedev S.A. Ispol’zovanie dinamicheskoi modeli agroekosistemy dlya otsenki vliyaniya klimaticheskikh izmenenii na produktivnost’ posevov [Using the dynamic model of the agroecosystem for estimating the influence of climatic changes on productivity of crops]. Vestnik Rossiiskoi akademii sel ’skokhozyaistvennykh nauk [Vestnik of the Russian agricultural science], 2012, no. 2, pp. 7-12. (In Russian).

30. Badenko V.L., Garmanov V.V., Ivanov D.A., Savchenko A.N., Topazh A.G. Perspektivy ispol’zovaniya dinamicheskikh modelei agroekosistem v zadachakh sredne- i dolgosrochnogo planirovaniya sel’skokhozyaistvennogo proizvodstva i zemleustroistva [Prospects of using dynamic models of agrosystems within the framework of medium- and long-term planning of agricultural production and land management]. Doklady Rossiiskoi akademii sel’skokhozyaistvennykh nauk [Reports of the Russian Academy of Agricultural Sciences], 2015, no. 1-2, pp. 72-76. (In Russian).

31. Medvedev S.A. Metodicheskie osnovy polivariantnogo rascheta dinamicheskikh modelei produktsionnogo protsessa sel’skokhozyaistvennykh kul’tur [Methodological basis of polyvariant calculation of dynamic models of agricultural crop production process]. AgroEkoInfo [AgroEcoInfo], 2015, no. 4, pp. 2-17. (In Russian).