Affiliation:
1. Southwest State University
Abstract
The purpose of the research is to develop a simulation model and tune the hyperparameters of a neural network to predict possible states of a network of small spacecraft.The research methods are based on the concepts of the theory of artificial intelligence to control a group of small spacecraft (SSV) – the use of adaptive methods and tools to make decisions, similar to the mechanisms of human thinking. In relation to space communication systems with a heterogeneous structure, artificial intelligence methods and technologies are aimed at predicting the state of communication channels between network nodes and automatically reconfiguring a network of devices based on neural network learning processes. One of the most important functions of network software for the application of cognitive algorithms is to predict the quality of communication between pairs of SSVs.Results. A method has been developed for using the Transformer architecture neural network to predict possible states of the SSV network, which provides aggregation and time synchronization of data on the state of the SSV network, their use for training the neural network, as well as using the neural network to predict the quality of communication. The data format for the training sample has been created, based on the representation of the state of the SSV network, which ensures the generation of the initial state of the network, modeling the proactive mode of its operation, collecting SSV network state markers to generate training data sets in the form of chronological sequences grouped into frames, and allowing to reduce the amount of data transferred between SSVs when creating a training set. A simulation model of the SSV network has been developed, which provides generation of the initial state of the network, modeling of the proactive mode of its operation, and collection of information about the state of the SSV network to generate sets of synthetic training data.Conclusion. The article develops a simulation model of the SSV network for generating synthetic training data and predicting possible states of the SSV network, as well as a method for using a neural network to predict possible states of the SSV network.
Publisher
Southwest State University
Reference20 articles.
1. Shilenkov E.A., Frolov S.N., Titenko E.A., Miroshnichenko S.Y. Selection of neural network architecture for implementing cognitive functions of network software for controlling a group of interacting small spacecraft. Izvestiya Yugo-Zapadnogo gosudarstvennogo universiteta. Seriya: Upravlenie, vychislitel'naya tekhnika, informatika. Meditsinskoe priborostroenie = Proceedings of the Southwest State University. Series: Control, Computer Engineering, Information Science. Medical Instruments Engineering. 2023;13(4):8–26. (In Russ.) https://doi.org/10.21869/2223-1536-2023-13-4-8-26
2. Aganesov A.V. Analysis of the quality of service in the aerospace communication network based on the hierarchical and decentralized principles of relaying information flows. Sistemy upravleniya, svyazi i bezopasnosti. = Control, Communication and Security Systems. 2015;(3):92–121. (In Russ.)
3. Novikov E.A., Utkin D.R., Shadrin A.G., Kvasov M.N. Assessing the timeliness of communication when transmitting multiservice traffic in a special-purpose satellite communication network. Sistemy upravleniya, svyazi i bezopasnosti = Control, Communication and Security Systems. 2018;(1):136–155. (In Russ.)
4. Sollogub A.V., Skobelev P.O., Simonova E.V., Tsarev A.V., Stepanov M.E., Zhilyaev A.A. Intelligent system for distributed control of group operations of a cluster of smallsized spacecraft in tasks of remote sensing of the Earth. Informatsionno-upravlyayushchie sistemy = Information and Control Systems. 2013;(1):16–26. (In Russ.)
5. Zhiqiang C., Krasnov A.Y., Duzhesheng L., Qiusheng Y. Dynamic surface control for omnidirectional mobile robot with full state constraints and input saturation. Scientific and Technical Journal of Information Technologies, Mechanics and Optics. 2023;23(6):1096–1105. https://doi.org/10.17586/2226-1494-2023-23-6-1096-1105