Validating Lithium-Polymer Battery Discharge Models to Ensure Uav Flight Safety and Performance
References
- Shcherban A, Eremenko V. UAV battery charge monitoring system using fuzzy logic. Studies in Systems, Decision and Control. 2023;481:195–221. doi:10.1007/978-3-031-35088-7_12.
- Shcherban AP, Larin VJ, Maslov VP, Kachur NV, Ryzhykh VM, Markina OM. Use of the infrared thermography method to develop discharging rules for lithium polymer batteries. Semiconductor Physics Quantum Electronics & Optoelectronics. 2019;22(2):252–6.
- International Organization for Standardization (ISO). Accuracy (trueness and precision) of measurement methods and results. Part 1. Basic provisions and definitions. ISO 5725-1:2005. Geneva: ISO; 2006.
- International Organization for Standardization (ISO). Statistics – Vocabulary and symbols. Part 1: General statistical terms and terms used in probability. ISO 35341:2008. Geneva: ISO; 2010.
- Xiang J, Liu Y, Luo Z. Flight safety measurements of UAVs in congested airspace. Chinese Journal of Aeronautics. 2016;29(5):1355–66.
- Liu Y, Zhang X, Guan X, Delahaye D. Adaptive sensitivity decision-based path planning algorithm for unmanned aerial vehicle with improved particle swarm optimization. Aerospace Science and Technology. 2016;58:92–102.
- Stolzer AJ. Safety management systems in aviation. Routledge; 2017.
- Oman H. Battery developments that will make electric vehicles practical. IEEE Aerospace & Electronics Systems Magazine. 2000;1(8):11–21.
- Shcherban AP, Larin VY. Pryncipy roboty ta osoblyvosti vykorystannia litii-polimernykh akumuliatoriv [Principles of operation and peculiarities of using lithium-polymer accumulators]. Tekhnolohichnyi Audyt ta Rezervy Vyrobnytstva [Technological Audit and Reserves of Production]. 2015;(3):83–8. [in Ukrainian].
- Scherban A, Larin V, Maslov V, Kachur N. Sensory information technologies for the safety of flight of unmanned aerial vehicles. Optoelectronics and Semiconductor Technology. 2019;54:96–111.
- Clothier RA, Walker RA. Safety risk management of unmanned aircraft systems. In: Handbook of Unmanned Aerial Vehicles. 2015. p. 2229–75.
- Shcherban AP, Larin VJ, Maslov VP, Kachur NV. Criterion for determining the period of energetically safe flight of unmanned aerial vehicles. Journal of Multidisciplinary Engineering Science Studies. 2018;4(11):2281–8.
DOI: https://doi.org/10.2478/tar-2024-0024 | Journal eISSN: 2545-2835
Language: English
Page range: 80 - 100
Submitted on: Dec 9, 2023
Accepted on: Dec 2, 2024
Published on: Dec 30, 2024
Published by: ŁUKASIEWICZ RESEARCH NETWORK – INSTITUTE OF AVIATION
In partnership with: Paradigm Publishing Services
Publication frequency: 4 issues per year
Keywords:
Related subjects:
© 2024 Anastasiia Shcherban, Vladymir Eremenko, published by ŁUKASIEWICZ RESEARCH NETWORK – INSTITUTE OF AVIATION
This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 License.