Choose A
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Code |
Training and Learning Results |
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A1 |
That the students demonstrate to possess and understand knowledge in an area of study that is part of the general education (second level), and often found at a level that, although based on advanced textbooks, also includes some aspects that involve knowledge from the avant-garde of the field of study |
|
A2 |
That the students know how to apply their knowledge to their work or vocation in a professional way and that they possess the competences that are usually demonstrated through the elaboration and defense of arguments and the resolution of problems within their area of study |
|
A3 |
That the students have the capability to gather and interpret relevant data (usually within their area of study) to issue judgments that include a reflection on relevant social, scientific or ethical issues |
|
A4 |
That the students can transmit information, ideas, problems and solutions to a specialized and non-specialized audience |
|
A5 |
That the students develop those learning capabilities necessary to undertake further studies with a high degree of autonomy. |
Choose B
|
Code |
Knowledge |
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B1 |
Capabiliity for design, development and management in the field of aeronautical engineering (in according with what is established in section 5 of order CIN / 308/2009), aerospace vehicles, aerospace propulsion systems, aerospace materials , airport infrastructures, air navigation infrastructures and space management, air traffic and transport management systems. |
|
B2 |
Planning, documentation, project management, calculation and manufacturing in the field of aeronautical engineering (in accordance with what is established in section 5 of order CIN / 308/2009), aerospace vehicles, propulsion systems, aerospace materials, airport infrastructures, air navigation infrastructures and space management, air traffic and transport management systems. |
|
B3 |
Installation, operation and maintenance in the field of aeronautical engineering (in accordance with what is established in section 5 of order CIN / 308/2009), aerospace vehicles, aerospace propulsion systems, aerospace materials, infrastructures and airports, air navigation infrastructures and space management, air traffic and transport management systems. |
|
B4 |
Verification and certification in the field of aeronautical engineering that aim, in accordance with the knowledge acquired (in accordance with what is established in section 5 of order CIN / 308/2009), aerospace vehicles, aerospace propulsion systems, aerospace materials, airport infrastructures, air navigation infrastructures and space management, air traffic and transport management systems. |
|
B5 |
Capability to carry out projection activities, technical management, expert training, drafting reports, opinions, and technical advice in tasks related to aeronautical technical engineering, exercise of functions with real aerospace character. |
|
B6 |
Capability to participate in flight testing programs for take-off and landing distances, ascent speeds, loss speeds, maneuverability and landing capacities. |
|
B7 |
Capability to analyze and assess the social and environmental impact of technical solutions. |
|
B8 |
Knowledge, understanding and capability to apply necessary legislation in the profession as aeronautical technical engineer. |
Choose C
|
Code |
Skill |
|
C1 |
Capability to solve mathematical problems that may arise in engineering. Aptitude to apply the knowledge about: linear algebra; geometry; differential geometry; differential and integral calculation; differential equations and partial derivatives; numerical methods; numerical algorithm; statistics and optimization. |
|
C2 |
Understanding and mastery of the basic concepts about the general laws of mechanics, thermodynamics, fields and waves and electromagnetism and their application to solve problems related to engineering. |
|
C3 |
Basic knowledge about use and programming of computers, operating systems, databases and software with application in engineering. |
|
C4 |
Capability to understand and apply the principles of basic and general chemistry, organic and inorganic chemistry and their application in engineering. |
|
C5 |
Capabiliity for spatial vision and knowledge of graphical representation techniques, both by traditional methods of metric geometry and descriptive geometry, as well as through computer aided design applications. |
|
C6 |
Adequate knowledge of the concept of a company, corporate and legal framework of a company. Organization and management of companies. |
|
C7 |
Understand the behavior of structures before their request in conditions of service and critical situations. |
|
C8 |
Understand thermodynamic cycles generating mechanical power and thrust. |
|
C9 |
Understand the overall nature of air navigation systems and the complexity of air traffic. |
|
C10 |
Understand how the aerodynamic forces determine the dynamics of the flight and the role of the different variables therein. |
|
C11 |
Understand the technological benefits, the techniques of optimization of the materials and the modification of their properties through treatments. |
|
C12 |
Understand manufacturing processes. |
|
C13 |
Understand the uniqueness of the infrastructures, buildings and operation of airports. |
|
C14 |
Understand the air transport system and the coordination with other transport modes. |
|
C15 |
Appropriate knowledge applied to engineering: Principles of the mechanics of continuous media and techniques for the calculation of their responses. |
|
C16 |
Appropriate knowledge applied to engineering: Concepts and laws that govern the processes of transfer of energy, the movement of fluids, the mechanisms of transmission of heat and the interchange of matter and its role in the analysis of the main propulsion systems in aerospace engineering. |
|
C17 |
Appropriate knowledge applied to engineering: Fundamental elements of the differente types of aircrafts; the functional elements of air navigation systems and associated electrical and electronic installations; foundations of the design and construction of airports. |
|
C18 |
Appropriate knowledge applied to the engineering: foundations of fluid mechanics; basic principles of control and automation of flight; main characteristics and physical and mechanical properties of the materials. |
|
C19 |
Applied knowledge of: science and technology of materials; mechanics and thermodynamics; fluid mechanics; aerodynamics and flight mechanics; navigation and air traffic systems; aerospace technology; theory of structures; airborne transportation; economy and production; projects; environmental impact. |
|
C20 |
Appropriate knowledge applied to engineering: mechanics of fracture of the continuous media and their dynamic behavior, fatigue of structural instability and aeroelasticity. |
|
C21 |
Appropriate knowledge applied to engineering: foundations of sustainability, maintenance and operation of aerospace vehicles. |
|
C22 |
Appropriate knowledge applied to engineering: foundations of fluid mechanics that describe the flow in all regimes, to determine the distributions of pressures and forces on an aircraft. |
|
C23 |
Appropriate knowledge applied to engineering: physical phenomena of flight, its qualities and its control, aerodynamics, propulsive forces, active control and stability. |
|
C24 |
Appropriate knowledge applied to engineering: systems of aircrafts and automatic systems of flight control of the aerospace vehicles. |
|
C25 |
Appropriate knowledge applied to engineering: methods of design calculations and aeronautical projects; use of aerodynamic experimentation and the most significant parameters in the theoretical application; management of experimental techniques, equipment and measuring instruments; simulation, design, analysis and interpretation of experimentation and operations in flight; systems of maintenance and certification of aircrafts. |
|
C26 |
Applied knowledge of aerodynamics; mechanics and thermodynamics, flight mechanics, aircraft engineering (fixed and rotary wings), theory of structures. |
|
C27 |
Appropriate knowledge applied to engineering: foundations of sustainability, maintainability and operation of space systems. |
|
C28 |
Appropriate knowledge applied to engineering: foundations of fluid mechanics that describe the flow in any regime and determine the distribution of pressures and aerodynamic forces. |
|
C29 |
Appropriate knowledge applied to engineering: concepts and laws that govern the internal combustion, its application to rocket propulsion. |
|
C30 |
Appropriate knowledge applied to engineering: technological benefits, techniques of optimization of the materials used in the aerospace sector and the processes of treatments to modify their mechanical properties. |
|
C31 |
Appropriate knowledge applied to engineering: physical phenomena of air defense systems, their qualities and their control, stability and automatic control systems. |
|
C32 |
Appropriate knowledge applied to engineering: methods of calculation and development of materials and defence systems; management of experimental techniques, equipment and measuring instruments; numerical simulation of the most significant physical-mathematical processes; inspection, quality control and fault detection techniques; their most appropriate methods and repair techniques. |
|
C33 |
Applied knowledge of aerodynamics, flight mechanics, air defense engineering (ballistics, missiles and air systems), space propulsion, material science and technology, structure theory. |
|
C34 |
Original exercise to be performed individually and presented and defended at a university jury, consisting of a project in the field of specific technologies of aerospace engineering with a professional nature in which the competences acquired during teaching are synthesized and integrated. |
Choose D
|
Code |
Competences |
|
D1 |
Capability of analysis, organization and planification. |
|
D2 |
Leadership, initiative and entrepreneurship |
|
D3 |
Capability of oral and written communication in native lenguage |
|
D4 |
Capability of autonomous learning and information management |
|
D5 |
Capability to solve problems and draw decisions |
|
D6 |
Capabiliity for interpersonal communication |
|
D7 |
Capability to adapt to new situations with creativity and innovation |
|
D8 |
Capabiliity for critical and self-critical reasoning |
|
D9 |
Capability to work in interdisciplinary teams |
|
D10 |
Capability to negotiate and deal with and act in situations of conflict |
|
D11 |
Show motivation for quality with sensitivity towards subjects within the scope of the studies |
|
D12 |
Ethical and democratic commitment |
|
D13 |
Sustainability and environmental commitment. Equitable, responsible and efficient use of resources |
Universidade de Vigo
|
Reitoría |
Campus Universitario |
C.P. 36.310 Vigo (Pontevedra) |
Spain |
Tlf: +34 986 812 000
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