Master of Aerospace Engineering  

Hybrid
English
Hybrid learning approach is applied in this study programme. Hybrid learning is an educational model where some students attend class in-person, while others join the class virtually from home. Curiosity, desire to construct, freedom to put your personal ideas into practice and develop a start-up - all these features fit under this master-degree study program. It is like a two-year long hackathon, where the science-based design of a prototype will become the major source of future skills. We see innovation in aeronautics as an interdisciplinary product, thereby your knowledge in the fields of electronics, mechanics, IT, transportation, aeronautics and any other branch of engineering will facilitate your team and provide the competitive advantage over the others. Everyone who seeks their education at the aeronautical engineering Master’s level should have background knowledge in aerodynamics, aircraft structures, mechanics and aircraft engine types. These courses are available online before the study process begins. All were prepared by the best technical universities in world including MIT, and TU Delft. The students of the current study program will develop the prototypes in teams, therefore individuals who seek like-minded partners or the groups with a unified idea are welcome to apply. The teams will be provided with the consultations by the experienced businesspeople, light on the start-up development will be shed by qualified mentors and the „Futurepreneurs“ programme. The aim of the study programme is to prepare highly qualified specialists who have acquired interdisciplinary and novel knowledge in the field of aeronautical engineering. These specialists are capable of constructing satellite systems and their elements, overcoming engineering challenges while developing industrial UAVs, conducting interdisciplinary research and applying the obtained results to prototype and innovation development. Experts and experienced scientists will help to put the project into practice in one of these fields: drones (UAVs), nano-satellites, 3D printing in aeronautics, military innovation in aeronautics. Outcome: Goals: 1. Educate highly skilled aviation mechanics specialists, having interdisciplinary and latest knowledge of aeronautics engineering study field and able to design aircraft cocpit installation and improvement modifications by coordinating technical solutions with the manufacturing institution, applying engineering methods and carrying out interdisciplinary research, to plan and supervise the work of aircraft technical maintenance personnel, employ life-long learning in order to participate in the global aviation engineering market. Results: 1. Knowledge Will know, understand and be able to apply fundamental knowledge of natural sciences and mathematics as well as principles of aeronautics engineering study field creatively and will be able to use them to solve new engineering problems. Will know and be able to critically assess the latest developments in engineering. 2. Research skills Will be able to plan and carry out analytical, modelling and experimental research, critically assess its data and draw conclusions. Will be able to analyse the applicability of new ways and methods for solving aerospace engineering problems 3. Engineering analysis Will be able to solve non-standard and incompletely defined problems, discern standard and non-standard problems in aerospace engineering, clearly formulate them, and apply innovative methods for solving specific problems and implement solutions. Will be able to use their knowledge and understanding to solve practical problems in aerospace engineering by applying theoretical models and research methods, including mathematical analysis, numerical modelling, and experimental methods. 4. Engineering design Will be able to apply the acquired knowledge and understanding to solve non-standard problems in aerospace engineering, among them problems related with other scientific and engineering fields. Will be able to implement innovative and original ideas and methods in aerospace engineering, make engineering decisions when confronted with multi-faceted, technically incomplete problems that are not accurately defined. 5. Personal and social abilities Will be able to work effectively both individually and in a team, be a leader of a team composed of members of various study fields and levels, to communicate with the engineering community and the general public both on a national and international level. Will have a holistic understanding of the impact of engineering activity on the society and environment, adhere to the norms of professional ethics and engineering activity, understand the responsibility for it, will have a deep understanding of project management and business aspects, also of the links between technical solutions and economic consequences. 6. Engineering practice ability Will be able to integrate knowledge from different study fields and solve multi-faceted engineering problems, to select appropriate engineering equipment and software. Will have knowledge of engineering activity organisation principles, understand interaction between its links, will be able to assess engineering activity in view of occupational health and safety and environmental aspects, and have knowledge of ethical, environmental, and commercial requirements for engineering activity.
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Master of Aerospace Engineering
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Upstream
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