The relevance of the research is determined by the leading role of state support in the effective functioning of agricultural organizations of the Voronezh region. The purpose of the article is to study theoretical approaches and justify practical ways to improve the efficiency of state support. The following research methods were used in the work on the article: analysis and synthesis, generalization, comparison, classification. Results. The concepts of state support, the effectiveness of state support are analyzed by the authors. The purpose, object and subject of this research are justified. The main provisions on which the evaluation of the effectiveness of state support in General, as well as auxiliary indicators for assessing the effectiveness of state support of agricultural organizations at the regional level should be based, are highlighted in the scientific work. Classification and analysis of existing methods of quantitative and qualitative assessment of the effectiveness of state support are given in the article. Some of them were tested with the use of available statistical data for agricultural organizations of the Voronezh region. Dynamic of volumes of state support of agricultural organizations and investment in agriculture, forestry, hunting for the Voronezh oblast for 2011–2016 is analyzed by the authors. The dynamic of relative indicators of the intensity of state support in the Voronezh region for the same period is presented. Indicators of efficiency of the state support of the agricultural organizations are calculated. The calculation of the indicators and factors of effectiveness of agricultural organizations taking into account the use of state support in the Voronezh region based on the method of S. Y. Petrova and O. A. Frolova spent in scientific work. The conclusion about the prospects of development of the regional agro-industrial complex taking into account the state support is made.

state support, effectiveness, agricultural organizations, Voronezh region

1. Ershov O.V. Ivanovskaya K.S., Chuprova L.V., Bagaeva, A.N.Modern composite materials based on polymer matrices. Mejdunarodni ijurnal prikladnih I fundamentalnih issledovanii [International journal of applied and fundamental research] 2015. no. 4 (1). pp. 14–18. (in Russian)

2. Amirov R.Kh., Isakayev E.Kh., Savelkin M.B., Shatalova T.B. Synthesis of carbo nanotubes in plazmotrona reactor in praesentia catalysts. Uspehiprikladnoifiziki [Progreditur in de physica]. 2014. vol. 2. no. 3. pp. 217–223. (in Russian)

3. Dutlov A.E., Nekrasov V.M., Sergeev A.G., Bubnov V.P. et al. Electric arc synthesis of soot with a high content of higher fullerenes in a "parallel arc". Jurnaltehnicheskoifiziki [Journal of Technical Physics]. 2016. vol. 86. no. 12. pp. 99–103. (in Russian)

4. Morozov I.V. Sculpturae clustered nanoplasma by MD. Nanostrukturi. Matematicheskaya fizika I modelirovanie [Nanostructures. Mathematica physicaetsculpturae]. 2011. vol. 5. no. 1–2. pp. 39–56. (in Russian)

5. Galkin V.A. Analiz matematicheskih modelei: sistemi zakono vsohraneniya uravneniya Bolcmanai Smoluhovskogo. [Analysis mathematica exempla: ratio de conservationeleges, Boltzmann aequationeet Smoluchow skiaequatio]. Moscow, BINOM. Nullascientia, 2009. 408 p. (in Russian)

6. Abramov G.V., Gavrilov A.N. The application of the large particles method of numerical modeling of the process of carbonic nanostructures synthesis in plasma. IOP Conf. Series: Journal of Physics: Conf. Series. 2018. no. 973. pp. 012-022. doi: 10.1088/1742–6596/973/1/012022

7. Abramov G.V., Gavrilov A.N., Tolstova I.S., Ivashin A.L. Formation of clusters of carbon structures in plasma under thermal destruction of graphite. Nanotechnologies in Russia. March 2017, vol. 12, issue 3, pp. 139–146. doi: 10.1134/S1995078017020021

8. Decyk V.K., Singh T.V. Particle-in-cell algorithms for emerging computer architectures. Computer Physics Communications. 2014. vol. 185. no 3. рр. 708–719.

9. GPGPU.RU In usura GPU pro calculis. (in Russian) Available at: http://www.gpgpu.ru/.

10. Cook S. CUDA programming. A Developer’s Guide to Parallel Computing with GPUs. Morgan Kaufmann. 2013. 576 p.