[
Ankersen, F. (2010). Guidance, Navigation, Control and Relative Dynamics for Spacecraft Proximity Maneuvers. PhD. thesis, Aalborg University, ISBN 978-87-92328-72-4.
]Search in Google Scholar
[
Apostolescu, N., Savu, T., Guță, D. D., & Ioniță, A. (2019). Industrial Robotics for Spacecraft Rendezvous and Docking Simulation. INCAS BULLETIN, Vol. 11, Issue 4, 27-36. Available at: https://doi.org/10.13111/2066-8201.2019.11.4.3
]Search in Google Scholar
[
Benninghoff, H., Remes, F., Risse, E.-A., & Mietner, C. (2017). European Proximity Operations Simulator 2.0 (EPOS) – A Robotic-Based Rendezvous and Docking Simulator. Journal of large-scale research facilities JLSRF, Vol. 3, A107. Available at: http://dx.doi.org/jlsrf-3-155-6.10.17815/jlsrf-3-155
]Search in Google Scholar
[
Costache, F., Nichifor, S.-E., Costea, M.-L., & Ioniță, A. (2021). Automatic Approach Procedure of a Flying Vehicle on a Mobile Platform Using Backstepping Controller. The 39th “Caius Iacob” Conference on Fluid Mechanics and its Technical Applications, Bucharest, 28-29 October.
]Search in Google Scholar
[
Ducard, G. J. J., & Allenspach, M. (2021). Review of Designs and Flight Control Techniques of Hybrid and Convertible VTOL UAVs. Aerospace Science and Technology, Vol. 118. Available at: https://doi.org/10.1016/j.ast.2021.107035.
]Search in Google Scholar
[
Fehse, W. (2003). Automated Rendezvous and Docking of Spacecraft, Cambridge University Press, ISBN 978-511-06240-7.10.1017/CBO9780511543388
]Search in Google Scholar
[
Guglieri, G., Maroglio, F., Pellegrino, P., & Torre, L. (2012). A Ground Facility to Test GNC Algorithms and Sensors for Autonomous Rendezvous and Docking. (IAA-AAS-DyCoSS1-09-03) (Part II). Available at: http://www.univelt.com/book=3758.
]Search in Google Scholar
[
Ioniță, A. et al. (2019). Air Cushion Robots Ground Testing Bed Experiments and Control Algorithm for Autonomous Rendezvous and Docking. IJMO, Vol. 9, No. 5, 277-284, ISSN 2010-3697.10.7763/IJMO.2019.V9.723
]Search in Google Scholar
[
Ioniță, A., Popescu, I. (2016). Attitude Dynamics and Tracking Control of Spacecraft in the Presence of Gravity Oblateness Perturbations. INCAS BULLETIN, Vol. 8, Issue 1, 85-97. Available at: http://dx.doi.org/10.13111/2066-8201.2016.8.1.9.10.13111/2066-8201.2016.8.1.9
]Search in Google Scholar
[
Neubauer, M., Günther, G., & Füllhas, K. (2007). Structural Design Aspects and Criteria for Military UAV. UAV Design Processes/Design Criteria for Structures, 1.2-1 – 1.2-2. Meeting Proceedings RTO-MP-AVT-145, Presentation 1.2. Neuilly-sur-Seine, France: RTO. Available at: http://www.rto.nato.int/abstracts.asp.
]Search in Google Scholar
[
Nguyen, T. V., Bordei, A. M., Nguyen, T. M., & Ioniță, A. (2019). Using PID Controller and SDRE methods for tracking control of Spacecrafts in Closed-Rendezvous Process. INCAS BULLETIN, Volume 11, Issue 1, 139-150, ISSN 2066-8201, doi: 10.13111/2066 8201.2019.11.1.11.10.13111/2066-8201.2019.11.1.11
]Search in Google Scholar
[
Saeed, A.S., Younes, A.B., Cai, C., & Cai, G. (2018), A Survey of Hybrid Unmanned Aerial Vehicles. Progress in Aerospace Sciences, Vol. 98, 91-105. Available at: https://doi.org/10.1016/j.paerosci.2018.03.007.
]Search in Google Scholar
[
Zappulla, R., Virgili-Llop, J., Park, H., Zagaris, C., & Romano, M. (2016). Floating Spacecraft Simulator Test Bed for the Experimental Testing of Autonomous Guidance, Navigation, and Control of Spacecraft Proximity Maneuvers and Operations. Available at: https://doi.org/10.2514/6.2016-5268.
]Search in Google Scholar
[
EERTIS – Engage in the European Research Infrastructures System. Available at: https://erris.gov.ro/SPACE-SYSTEM-LABORATORY.
]Search in Google Scholar
[
*** UAV platforms with dedicated capabilities and support infrastructure for applications in national security missions, Stage A, INCAS Technical report, “Features of static and dynamic stability for UAV systems”, 2019.
]Search in Google Scholar
[
*** STAR – Guidance, Navigation and CONtrol TECHnologies for SATellite Systems, CONTECHSAT, Ctr. Nr. 117/2016, 2016-2019.
]Search in Google Scholar
