Comparative Analysis of Intellectual Approaches to Solving the Situation Identification Problem
Authors: Buldakova T.I., Suyatinov S.I., Vishnevskaya Yu.A.  | Published: 19.06.2024 |
Published in issue: #2(147)/2024 | |
DOI: | |
Category: Informatics, Computer Engineering and Control | Chapter: System Analysis, Control, and Information Processing | |
Keywords: situation identification, intelligent technologies, neural networks, synergy model, associativity, information ranking |
Abstract
The paper examines application of two intelligent methods in identifying situations based on the associativity property, i.e., the ability to access the stored data using its content. In comparative analysis, the Hopfield neural network as a representative of the neural networks and the Haken synergetic model as an alternative approach to identification are selected. Their characteristics are provided, as well as similarities and differences between them. Operation of these models implemented in the Python programming language was practically studied, and results of the situation identification are presented using the example of identifying a threat category in the helicopter control. Study results demonstrate that the synergetic model is more accurate in identifying the threat category. During the experiments, disadvantages and advantages of each intelligent method were revealed. In particular, the Hopfield neural network shows
a number of disadvantages critical in situations that require a prompt and accurate solution. The synergy model has a number of advantages compared to the neural network, they include absence of the false attractors and ability to rank information by setting the appropriate parameter values
Please cite this article in English as:
Buldakova T.I., Suyatinov S.I., Vishnevskaya Yu.A. Comparative analysis of intellectual approaches to solving the situation identification problem. Herald of the Bauman Moscow State Technical University, Series Instrument Engineering, 2024, no. 2 (147), pp. 84--101 (in Russ.). EDN: RIGGLQ
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