This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
Mohsan, S.A.H., Khan, M.A., Noor, F., Ullah, I. and Alsharif, M.H. “Towards the Unmanned Aerial Vehicles (UAVs): A Comprehensive Review.” Drones Vol. 6 (2022): p. 147. DOI 10.3390/drones6060147.MohsanS.A.H.KhanM.A.NoorF.UllahI.AlsharifM.H. “Towards the Unmanned Aerial Vehicles (UAVs): A Comprehensive Review.” Vol. 6 (2022): p. 147. DOI 10.3390/drones6060147.Open DOISearch in Google Scholar
Nex, F., Armenakis, C., Cramer, M., Cucci, D.A., Gerke, M., Honkavaara, E., Kukko, A., Persello, C. and Skaloud, J. “UAV in the Advent of the Twenties: Where We Stand and What is Next.” ISPRS Journal of Photogrammetry and Remote Sensing Vol. 184 (2022): pp. 215–242. DOI 10.1016/j.isprsjprs.2021.12.006.NexF.ArmenakisC.CramerM.CucciD.A.GerkeM.HonkavaaraE.KukkoA.PerselloC.SkaloudJ. “UAV in the Advent of the Twenties: Where We Stand and What is Next.” Vol. 184 (2022): pp. 215–242. DOI 10.1016/j.isprsjprs.2021.12.006.Open DOISearch in Google Scholar
Di, L. “Tian Loong I Fire Fight UAV.” 2019. Available at: https://k.sina.com.cn/article_1726918143_66eeadff02000tkw2.html (accessed on 6 September 2021).DiL. “.” 2019. Available at: https://k.sina.com.cn/article_1726918143_66eeadff02000tkw2.html (accessed on 6 September 2021).Search in Google Scholar
Alappatt, T.B., Ajith, S.S., Jose, J., Augustine, J., Sankar, V. and George, J.M. “Design and Analysis of Fire Fighting Drone.” In: Sengodan, T., Murugappan, M. and Misra, S. (eds). Advances in Electrical and Computer Technologies. ICAECT 2020. Lecture Notes in Electrical Engineering, Vol. 711. Springer, Singapore (2021). DOI 10.1007/978-981-15-9019-1_85.AlappattT.B.AjithS.S.JoseJ.AugustineJ.SankarV.GeorgeJ.M.“Design and Analysis of Fire Fighting Drone.” In: SengodanT.MurugappanM.MisraS. (eds). , Vol. 711. Springer, Singapore (2021). DOI 10.1007/978-981-15-9019-1_85.Open DOISearch in Google Scholar
Alghamdi, Yousef, Munir, Arslan and La, Hung Manh. “Architecture, Classification, and Applications of Contemporary Unmanned Aerial Vehicles.” IEEE Consumer Electronics Magazine Vol. 10 No. 6 (2021): pp. 9–20. DOI 10.1109/MCE.2021.3063945.AlghamdiYousefMunirArslanLaHung Manh. “Architecture, Classification, and Applications of Contemporary Unmanned Aerial Vehicles.” Vol. 10 No. 6 (2021): pp. 9–20. DOI 10.1109/MCE.2021.3063945.Open DOISearch in Google Scholar
Chiang, W.C., Li, Y., Shang, J. and Urban, T.L. “Impact of Drone Delivery on Sustainability and Cost: Realizing the UAV Potential Through Vehicle Routing Optimization.” Applied Energy Vol. 242 (2019): pp. 1164–1175.ChiangW.C.LiY.ShangJ.UrbanT.L. “Impact of Drone Delivery on Sustainability and Cost: Realizing the UAV Potential Through Vehicle Routing Optimization.” Vol. 242 (2019): pp. 1164–1175.Search in Google Scholar
Cevik, P., Kocaman, I., Akgul, A.S. and Akca, B. “The Small and Silent Force Multiplier: A Swarm UAV – Electronic Attack.” Journal of Intelligent and Robotic Systems Vol. 70 (2013): pp. 595–608.CevikP.KocamanI.AkgulA.S.AkcaB. “The Small and Silent Force Multiplier: A Swarm UAV - Electronic Attack.” Vol. 70 (2013): pp. 595–608.Search in Google Scholar
Martins, Bruno, Oliveira, Arthur, Holland Michel, and Andrea, Silkoset. “Countering the Drone Threat: Implications of C-Uas Technology for Norway in an EU and NATO Context.” PRIO Paper. PRIO, Oslo. 2020.MartinsBrunoOliveiraArthurMichelHollandAndreaSilkoset. “Countering the Drone Threat: Implications of C-Uas Technology for Norway in an EU and NATO Context.” . PRIO, Oslo. 2020.Search in Google Scholar
Antonio, Calcara, Andrea, Gilli, Mauro, Gilli, Raffaele, Marchetti, R. and Ivan Zaccagnini. “Why Drones have not Revolutionized War: The Enduring Hider-Finder Competition in Air Warfare.” International Security Vol. 46 No. 4 (2022): pp. 130–171. DOI 10.1162/isec_a_00431.AntonioCalcaraAndreaGilliMauroGilliRaffaeleMarchettiR.ZaccagniniIvan “Why Drones have not Revolutionized War: The Enduring Hider-Finder Competition in Air Warfare.” Vol. 46 No. 4 (2022): pp. 130–171. DOI 10.1162/isec_a_00431.Open DOISearch in Google Scholar
Park, S., Kim, H.T., Lee, S., Joo, H. and Kim, H. “Survey on Anti-Drone Systems: Components, Designs, and Challenges.” IEEE Access Vol. 9 (2021): pp. 42635–42659. DOI 10.1109/ACCESS.2021.3065926.ParkS.KimH.T.LeeS.JooH.KimH. “Survey on Anti-Drone Systems: Components, Designs, and Challenges.” Vol. 9 (2021): pp. 42635–42659. DOI 10.1109/ACCESS.2021.3065926.Open DOISearch in Google Scholar
Yaacoub, J.-P., Noura, H., Salman, O. and Chehab, A. “Security Analysis of Drones Systems: Attacks, Limitations, and Recommendations.” Internet of Things Vol. 11 (2020): p. 100218. DOI 10.1016/j.iot.2020.100218..YaacoubJ.-P.NouraH.SalmanO.ChehabA. “Security Analysis of Drones Systems: Attacks, Limitations, and Recommendations.” Vol. 11 (2020): p. 100218. DOI 10.1016/j.iot.2020.100218..Open DOISearch in Google Scholar
Palomba, G., Crupi, V. and Epasto, G. “Additively Manufactured Lightweight Monitoring Drones: Design and Experimental Investigation.” Polymer Vol. 241 (2022): p. 124557. DOI 10.1016/j.polymer.2022.124557.PalombaG.CrupiV.EpastoG. “Additively Manufactured Lightweight Monitoring Drones: Design and Experimental Investigation.” Vol. 241 (2022): p. 124557. DOI 10.1016/j.polymer.2022.124557.Open DOISearch in Google Scholar
Sally Cole Johnson. “High-Energy Laser Weaponry Delivers Speed-of-Light ‘Hard Kills’ to Drones.” 2022. Available at: https://www.laserfocusworld.com/lasers-sources/article/14277939/highenergy-laser-weaponry-delivers-speedoflight-hard-kills-to-drones, access date 04.04.2023Sally Cole Johnson. “.” 2022. Available at: https://www.laserfocusworld.com/lasers-sources/article/14277939/highenergy-laser-weaponry-delivers-speedoflight-hard-kills-to-drones, access date 04.04.2023Search in Google Scholar
Lionis, A., Tsigopoulos, A. and Cohn, K. “An Application of Artificial Neural Networks to Estimate the Performance of High-Energy Laser Weapons in Maritime Environments.” Technologies Vol. 10 (2022): p. 71. DOI 10.3390/technologies10030071.LionisA.TsigopoulosA.CohnK. “An Application of Artificial Neural Networks to Estimate the Performance of High-Energy Laser Weapons in Maritime Environments.” Vol. 10 (2022): p. 71. DOI 10.3390/technologies10030071.Open DOISearch in Google Scholar
Bernatskyi, A. and Sokolovskyi, M. “History of Military Laser Technology Development in Military Applications.” History of Science and Technology Vol. 12 No. 1 (2022): pp. 88–113. DOI 10.32703/2415-7422-2022-12-1-88-113.BernatskyiA.SokolovskyiM. “History of Military Laser Technology Development in Military Applications.” Vol. 12 No. 1 (2022): pp. 88–113. DOI 10.32703/2415-7422-2022-12-1-88-113.Open DOISearch in Google Scholar
Haim, Abitan, Henrik, Bohr, and Preben, Buchhave, “Correction to the Beer-Lambert-Bouguer Law for Optical Absorption.” Applied Optics Vol. 47 (2008): pp. 5354–5357. DOI 10.1364/AO.47.005354.HaimAbitanHenrikBohrPrebenBuchhave “Correction to the Beer-Lambert-Bouguer Law for Optical Absorption.” Vol. 47 (2008): pp. 5354–5357. DOI 10.1364/AO.47.005354.Open DOISearch in Google Scholar
Thangavel, Prabhu, and Ajay, Sekar. “Investigations on Heat Transfer Characteristics of Porous Type Copper Heat Sink with Bifurcations.” Journal of Thermal Engineering Vol. 7 No. 3 (2021): pp. 584–594.ThangavelPrabhuAjaySekar. “Investigations on Heat Transfer Characteristics of Porous Type Copper Heat Sink with Bifurcations.” Vol. 7 No. 3 (2021): pp. 584–594.Search in Google Scholar
Pavlenko, D., Dvirnyk, Y. and Przysowa, R. “Advanced Materials and Technologies for Compressor Blades of Small Turbofan Engines.” Aerospace Vol. 8 (2021): p. 1. DOI 10.3390/aerospace8010001.PavlenkoD.DvirnykY.PrzysowaR. “Advanced Materials and Technologies for Compressor Blades of Small Turbofan Engines.” Vol. 8 (2021): p. 1. DOI 10.3390/aerospace8010001.Open DOISearch in Google Scholar
Williams, J.C. and Boyer, R.R. “Opportunities and Issues in the Application of Titanium Alloys for Aerospace Components.” Metals Vol. 10 (2020): p. 705. DOI 10.3390/met10060705.WilliamsJ.C.BoyerR.R. “Opportunities and Issues in the Application of Titanium Alloys for Aerospace Components.” Vol. 10 (2020): p. 705. DOI 10.3390/met10060705.Open DOISearch in Google Scholar
Bytkin, S.V. “Thermal and Radiation Resistant Materials for Space Electronics.” In: Bytkin, S.V., Kritskaya, T.V., Karpenko, H.V. and Yanko, T.B. (eds). Space Technologists: Present and Future: Abstract. Report of the 4th International Conference: p. 94. Dnepropetrovsk, April 17–19, 2013.BytkinS.V. “Thermal and Radiation Resistant Materials for Space Electronics.” In: BytkinS.V.KritskayaT.V.KarpenkoH.V.YankoT.B. (eds). : p. 94. Dnepropetrovsk, April17–19, 2013.Search in Google Scholar
Park, S.J. (2018). “Carbon Carbon Composites.” In: Carbon Fibers. Springer Series in Materials Science, Vol. 210. Springer, Singapore, pp. 279–294. DOI 10.1007/978-981-13-0538-2_8.ParkS.J. (2018). “Carbon Carbon Composites.” In: , Vol. 210. Springer, Singapore, pp. 279–294. DOI 10.1007/978-981-13-0538-2_8.Open DOISearch in Google Scholar
Zelin, Wang, Bingzhu, Lai, Hui, Wang, Heye, Xiao, and Pingwen, Ming, Effects of Micropore Characteristics in the Metal Skeleton on Heat and Mass Transfer in an Open Foam Structure for Thermal Management in the Hydrogen UAV.” International Journal of Thermal Sciences Vol. 179 (2022): p. 107628. DOI 10.1016/j.ijthermalsci.2022.107628.ZelinWangBingzhuLaiHuiWangHeyeXiaoPingwenMingEffects of Micropore Characteristics in the Metal Skeleton on Heat and Mass Transfer in an Open Foam Structure for Thermal Management in the Hydrogen UAV.” Vol. 179 (2022): p. 107628. DOI 10.1016/j.ijthermalsci.2022.107628.Open DOISearch in Google Scholar
AL-Saleem, Nouf K., Ghrib, Taher, AL-Naghmaish, Aishah, Elshekhipy, Abdelhafeez A., Almalki, Nawal, Gmati, Nabil, and Kamoun Turki, Najoua. Effect of Porosity on Structural, Optical, Thermal, and Electrical Properties of Nickel-Foam Coated Graphene Sheets.” Journal of Materials Research and Technology Vol. 19 (2022): pp. 300–313. DOI 10.1016/j.jmrt.2022.05.049.AL-SaleemNouf K.GhribTaherAL-NaghmaishAishahElshekhipyAbdelhafeez A.AlmalkiNawalGmatiNabilKamoun TurkiNajoua.Effect of Porosity on Structural, Optical, Thermal, and Electrical Properties of Nickel-Foam Coated Graphene Sheets.” Vol. 19 (2022): pp. 300–313. DOI 10.1016/j.jmrt.2022.05.049.Open DOISearch in Google Scholar
Dyga, R. and Witczak, S. “Investigation of Effective Thermal Conductivity Aluminum Foams.” Procedia Engineering Vol. 42 (2012): pp. 1088–1099. DOI 10.1016/j.proeng.2012.07.500.DygaR.WitczakS. “Investigation of Effective Thermal Conductivity Aluminum Foams.” Vol. 42 (2012): pp. 1088–1099. DOI 10.1016/j.proeng.2012.07.500.Open DOISearch in Google Scholar
Lu, Pengbo, Cheng, Fan, Ou, Yanghao, Lin, Meiyan, Su, Lingfeng, Chen, Size, Yao, Xilang, and Liu, Detao. “A Flexible and Transparent Thin Film Heater Based on a Carbon Fiber/Heat-Resistant Cellulose Composite.” Composites Science and Technology Vol. 153 (2017): pp. 1–6. DOI 10.1016/j.compscitech.2017.09.033.LuPengboChengFanOuYanghaoLinMeiyanSuLingfengChenSizeYaoXilangLiuDetao. “A Flexible and Transparent Thin Film Heater Based on a Carbon Fiber/Heat-Resistant Cellulose Composite.” Vol. 153 (2017): pp. 1–6. DOI 10.1016/j.compscitech.2017.09.033.Open DOISearch in Google Scholar
Lee, Sora, Jang, Dawon, Chung, Yong Sik, and Lee, Sungho “Cost-Effective and Highly Efficient Surface Heating Elements using High Thermal Conductive Carbon Fibers.” Composites Part A: Applied Science and Manufacturing Vol. 137 (2020): p. 105992.LeeSoraJangDawonChungYong SikLeeSungho “Cost-Effective and Highly Efficient Surface Heating Elements using High Thermal Conductive Carbon Fibers.” Vol. 137 (2020): p. 105992.Search in Google Scholar
Hu, J.; Jahid, M.A.; Harish Kumar, N.; Harun, V. Fundamentals of the Fibrous Materials. In Handbook of Fibrous Materials; Wiley Online Library: Hoboken, NJ, USA, 2020; pp. 1–36. DOI 10.1002/9783527342587.ch1.HuJ.JahidM.A.Harish KumarN.HarunV.Fundamentals of the Fibrous Materials. In ; Wiley Online Library: Hoboken, NJ, USA, 2020; pp. 1–36. DOI 10.1002/9783527342587.ch1.Open DOISearch in Google Scholar
Shcherbakova, E.P., Prokhorova, A.D., Karpenko, A.V. and Yanko, T.B. “Current State of Methods for Low-Dense Constructional Composite Materials Producing (Overview).” Problems of Atomic Science and Technology (Past) Vol. 125 No. 1 (2020): pp. 114–120.ShcherbakovaE.P.ProkhorovaA.D.KarpenkoA.V.YankoT.B. “Current State of Methods for Low-Dense Constructional Composite Materials Producing (Overview).” Vol. 125 No. 1 (2020): pp. 114–120.Search in Google Scholar
Sharma, R., Ravikumar, N.L., Dasgupta, K., Chakravartty, J.K. and Kar, K.K. “Advanced Carbon–Carbon Composites: Processing Properties and Applications.” In: Kar, K. (ed). Composite Materials. Springer, Berlin, Heidelberg (2017), pp. 315–367. DOI 10.1007/978-3-662-49514-8_10.SharmaR.RavikumarN.L.DasguptaK.ChakravarttyJ.K.KarK.K. “Advanced Carbon–Carbon Composites: Processing Properties and Applications.” In: KarK. (ed). . Springer, Berlin, Heidelberg (2017), pp. 315–367. DOI 10.1007/978-3-662-49514-8_10.Open DOISearch in Google Scholar
Skachkov, V. A. “Obtaining Low-Density Carbon Carbonized Materials.” In: Skachkov, V.A., Chervonny, I.F. and Karpenko, A.V. (eds). Eastern European Journal of Advanced Technologies, Kharkiv (2013): pp. 48–51.SkachkovV. A. “Obtaining Low-Density Carbon Carbonized Materials.” In: SkachkovV.A.ChervonnyI.F.KarpenkoA.V. (eds). , Kharkiv (2013): pp. 48–51.Search in Google Scholar