MODELING OF INTELLECTUAL TECHNOLOGY FOR CALCULATING THE INTEGRAL INDICATOR OF COMPETITIVENESS OF AN E-COMMERCE ENTERPRISE

Authors

DOI:

https://doi.org/10.28925/2663-4023.2023.20.239252

Keywords:

integral indicator of competitiveness of a trade enterprise; intelligent information technology; decomposition of the information technology model; CASE-technologies; data preparation algorithm; convolutional neural network (CNN); quality metrics of information intelligent decision-making systems

Abstract

The use of modern achievements of scientific and technological progress is crucial in building information systems and implementing information technologies. Recently, artificial neural networks have been used to solve several data classification and clustering tasks, which allow achieving extraordinary accuracy. The availability of a large number of software and hardware tools for creating and training artificial neural networks, as well as the ability to use a large amount of data (including data from real enterprises) to train networks on it, allows you to quickly build effective models for solving various problems, including economic ones. In today's conditions, tracking and calculating the dynamics of the integral indicator of competitiveness of an e-commerce enterprise is one of the main indicators of the state of the enterprise in the economic space of the state. Accordingly, to calculate and model situations related to the calculation of the dynamics of the integral indicator of competitiveness of an e-commerce enterprise, it is worth applying neural network models for processing and analyzing a large amount of data. This approach allows optimizing enterprise management processes, increasing the personalization of service and ensuring effective interaction with customers, etc. The considered convolutional neural network has such special properties as self-organization, the ability to learn in the process of work, generalization, simulation of processes and phenomena, including nonlinear ones, formation of complex dependencies in the space of diagnostic events, efficiency of work with high-dimensional features, which determine the expediency of their use for solving forecasting problems, in particular, calculation and modeling of situations related to the calculation of the dynamics of the integral indicator of competitiveness of an e-commerce enterprise.

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References

W. Huang, K. K. Lai, Y. Nakamori, S. Wang, and L. Yu, “Neural networks in finance and economics forecasting,” International Journal of Information Technology & Decision Making, vol. 06, no. 01, pp. 113–140, 2007. https://doi.org/10.1142/S021962200700237X

C. J. Neely, D. E. Rapach, J. Tu, and G. Zhou, “Forecasting the Equity Risk Premium: The Role of Technical Indicators” Management Science, vol. 60, pp. 1772–1791, July 2014. https://www.jstor.org/stable/42919633

T. Zoumpekas, E. Houstis, and M. Vavalis, “Eth analysis and predictions utilizing deep learning,” Expert Systems with Applications, vol. 162, p. 113866, 2020. https://doi.org/10.1016/j.eswa.2020.113866

Ertz, M., & Boily, É. (2019). The rise of the digital economy: Thoughts on blockchain technology and cryptocurrencies for the collaborative economy. International Journal of Innovation Studies, 3(4), 84-93. https://doi.org/10.1016/j.ijis.2019.12.002

Zhang, P., Schmidt, D. C., White, J., & Dubey, A. (2019). Consensus mechanisms and information security technologies. Advances in Computers, 115, 181-209. https://www.dre.vanderbilt.edu/~schmidt/PDF/CH0007_Deka_v8.pdf

Chen, W., Xu, H., Jia, L., & Gao, Y. (2021). Machine learning model for Bitcoin exchange rate prediction using economic and technology determinants. International Journal of Forecasting, 37(1), 28-43. https://doi.org/10.1016/j.ijforecast.2020.02.008

Akhmetov, B. et al. (2022). A Model for Managing the Procedure of Continuous Mutual Financial Investment in Cybersecurity for the Case with Fuzzy Information. In: Karrupusamy, P., Balas, V.E., Shi, Y. (eds) Sustainable Communication Networks and Application. Lecture Notes on Data Engineering and Communications Technologies, vol 93. Springer, Singapore. https://doi.org/10.1007/978-981-16-6605-6_40

Lakhno, V., Malyukov, V., Kasatkin, D., Vlasova, G., Kravchuk, P., Kosenko, S. (2020). Model for Choosing Rational Investment Strategies, with the Partner’s Resource Data Being Uncertain. In: Silhavy, R., Silhavy, P., Prokopova, Z. (eds) Software Engineering Perspectives in Intelligent Systems. CoMeSySo 2020. Advances in Intelligent Systems and Computing, vol 1295. Springer, Cham. https://doi.org/10.1007/978-3-030-63319-6_29 1.

Akhmetov, Bakhytzhan, Berik Akhmetov, Valeriy Lakhno and Volodymyr Malyukov. “Adaptive model of mutual financial investment procedure control in cybersecurity systems of situational transport centers.” NEWS of National Academy of Sciences of the Republic of Kazakhstan (2019) DOI:10.32014/2019.2518-170X.82

Lakhno, V., Malyukov, V., Gerasymchuk, N., & Shtuler, I. (2017). Development of the decision making support system to control a procedure of financial investment. Eastern-European Journal of Enterprise Technologies, 6(3 (90), 35–41. https://doi.org/10.15587/1729-4061.2017.119259

Akhmetov, B., Lakhno, V., Malyukov, V., Sarsimbayeva, S., Zhumadilova, M., Kartbayev, T. Decision support system about investments in smart сity in conditions of incomplete information (2019) International Journal of Civil Engineering and Technology, 10 (2), pp. 661-670. http://iaeme.com/Home/issue/IJCIET?Volume=10&Issue=2

M. Ali and S. Shatabda, "A Data Selection Methodology to Train Linear Regression Model to Predict Bitcoin Price," 2020 2nd International Conference on Advanced Information and Communication Technology (ICAICT), Dhaka, Bangladesh, 2020, pp. 330-335, doi: 10.1109/ICAICT51780.2020.9333525.

T. Law & J. Shawe-Taylor (2017) Practical Bayesian support vector regression for financial time series prediction and market condition change detection, Quantitative Finance, 17:9, 1403-1416, DOI: 10.1080/14697688.2016.1267868

Alymova E. V., Kudryavtsev O. E. Neural networks usage for financial time series prediction. Abstracts of Talks Given at the 4th International Conference on Stochastic Methods // Theory of Probability & Its Applications, 2020, Vol. 65, № 1, pp. 122-123. DOI: 10.3390/e24050657

Tim Hill, Leorey Marquez, Marcus O'Connor, William Remus, Artificial neural network models for forecasting and decision making, International Journal of Forecasting, Volume 10, Issue 1, 1994, Pages 5-15, ISSN 0169-2070, https://doi.org/10.1016/0169-2070(94)90045-0.

Alev Taskin Gumus, Ali Fuat Guneri, Selcan Keles, Supply chain network design using an integrated neuro-fuzzy and MILP approach: A comparative design study, Expert Systems with Applications, Volume 36, Issue 10, 2009, Pages 12570-12577, ISSN 0957-4174, https://doi.org/10.1016/j.eswa.2009.05.034.

Pankratov, Vladimir Andreevich. "Strategy for the Development of Socio-Economic Systems Based on the Methodologies of Foresight and Cognitive Modeling." (2017). Dissertation for the degree of Candidate of Technical Sciences, Specialty 01.05.04 - System Analysis and Theory of Optimal Solutions. Kyiv, 2017.

Bebeshko, B. (2022). Analysis of digital cryptocurrency market forecasting methods and models. Electronic Professional Scientific Edition «Cybersecurity: Education, Science, Technique», 2(18), 163–174. https://doi.org/10.28925/2663-4023.2022.18.163174

Morshedi, M. A., & Kashani, H. (2022). Assessment of vulnerability reduction policies: Integration of economic and cognitive models of decision-making. Reliability Engineering & System Safety, 217, 108057. https://doi.org/10.1016/j.ress.2021.108057

Bourgin, D. D., Peterson, J. C., Reichman, D., Russell, S. J., & Griffiths, T. L. (2019, May). Cognitive model priors for predicting human decisions. In International conference on machine learning (pp. 5133-5141). PMLR. https://doi.org/10.48550/arXiv.1905.09397

Thomson, R., Lebière, C., Anderson, J. R., & Staszewski, J. J. (2015). A general instance-based learning framework for studying intuitive decision-making in a cognitive architecture.. Journal of Applied Research in Memory and Cognition, 4(3), 180-190. https://doi.org/10.1016/j.jarmac.2014.06.002.

Sun, R. (2006). Prolegomena to integrating cognitive modeling and social simulation. Cognition and multi-agent interaction: from cognitive modeling to social simulation, 3-26.

Busemeyer, J. R., & Diederich, A. (2010). Cognitive modeling. Sage.

Gilboa, I., Schmeidler, D. A cognitive model of individual well-being. Soc Choice Welfare 18, 269–288 (2001). https://doi.org/10.1007/s003550100103.

Song, G. Y., Cheon, Y., Lee, K., Lim, H., Chung, K. Y., & Rim, H. C. (2014). Multiple categorizations of products: cognitive modeling of customers through social media data mining. Personal and ubiquitous computing, 18, 1387-1403.

Margaritis, M., Stylios, C., & Groumpos, P. (2002, October). Fuzzy cognitive map software. In 10th international conference on software, telecommunications and computer networks SoftCom (Vol. 2002, pp. 8-11).

Margaritis, M., Fidas, C., & Avouris, N. (2007). A framework to facilitate building of collaborative learning applications. Advanced Technology for Learning, 4(1), 24-29.

Yethiraj, N. G. (2012). Applying data mining techniques in the field of agriculture and allied sciences. International Journal of Business Intelligents ISSN, 2278-2400.

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Published

2023-06-29

How to Cite

Kharchenko, O., & Yaremych, V. (2023). MODELING OF INTELLECTUAL TECHNOLOGY FOR CALCULATING THE INTEGRAL INDICATOR OF COMPETITIVENESS OF AN E-COMMERCE ENTERPRISE. Electronic Professional Scientific Journal «Cybersecurity: Education, Science, Technique», 4(20), 239–252. https://doi.org/10.28925/2663-4023.2023.20.239252

Issue

Vol. 4 No. 20 (2023): Cybersecurity: Education, Science, Technique

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Copyright (c) 2023 Олександр Харченко, Валентин Яремич

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