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Fundamental
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The ability to solve mathematical problems which may arise in engineering. The aptitude to apply knowledge about: Linear algebra; geometry; differential geometry; differential and integral calculus; differential and partial differential equations; numerical methods; algorithms; statistics and optimisation.
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Understanding and command of the basic concepts of the general laws of mechanics, thermodynamics, fields and waves, as well as electromagnetic fields and their application to solve engineering problems.
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Basic knowledge of the use and programming of computers such as operating systems, databases and software programmes used in engineering.
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The ability to understand and apply the basic principles of general, organic and inorganic chemistry, and its applications in Engineering.
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The ability to view things spatially and be knowledgeable about graphic drawing techniques, both traditional methods of metric and descriptive geometry, as well as Computer Aided Design.
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Adequate knowledge of the concepts of business, and the institutional and legal frameworks of business. Business organisation and business management.
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Understanding the behaviour of structures in light of requests and in conditions of service and extreme situations.
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The ability to take part in flight test programmes for collecting data on take-off distances, rates of ascent, stall speeds, manoeuvrability and landing capabilities.
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The ability to communicate in a foreign language, ideally English, both in writing and orally.
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Understanding the thermodynamic cycles that generate mechanical power and thrust.
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Understanding all aspects of air navigation systems and the complexity of air traffic.
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Understanding how aerodynamic forces determine flight dynamics and the role different variables play in the phenomenon of flight.
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Understanding the technological features and techniques for optimizing materials and modifying their properties via processing.
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Understanding manufacturing processes
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Understanding the uniqueness of the infrastructure, buildings and functionality of airports.
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Understanding the system of air transport and its coordination with other modes of transport.
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Adequate and applied knowledge of the following engineering concepts: Principles of continuum mechanics and the calculation techniques used for problem-solving.
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Adequate and applied knowledge of the following engineering concepts: Concepts and laws which govern the processes of energy transfer, fluid motion, heat and mass transfer mechanisms and their role in the analysis of the main aerospace propulsion systems.
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Adequate and applied knowledge of the following engineering concepts: Fundamental elements of different aircraft; functional elements of air navigation systems and their associated electrical and electronic systems; fundamental elements of design and construction of airports and their diverse elements.
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Adequate and applied knowledge of the following engineering concepts: Fundamentals of fluid mechanics; basic principles of control and flight automation; main characteristics of materials and their physical and mechanical properties.
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Applied knowledge of: Science and technology of materials; mechanics and thermodynamics; fluid mechanics, aerodynamics and flight mechanics; air navigation and air traffic systems; aerospace technology; structural mechanics; air transport; economics and manufacturing; design; environmental impact.
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The ability to draft, sign and develop projects in the field of Aeronautical Engineering. Planning, drafting, directing and managing projects, calculation and manufacturing in the field of aeronautical engineering which aims to develop, in accordance with acquired knowledge, aerospace vehicles, aerospace propulsion systems, aerospace materials, airport facilities, air navigation systems and any other system of space management, air traffic and air transport.
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The ability to handle obligatory specifications, regulations and standards.
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Knowledge and understanding of the economic and financial aspects of the company. Adequate knowledge of business concepts and the institutional and legal frameworks of business. Business organisation and business management.
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The ability to analyse and assess the social and environmental impact of technical solutions. Social, ethical and environmental commitment to the development of compatible and sustainable engineering solutions thoroughly in tune with the reality of the human and natural environment.
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The knowledge, understanding, and ability to apply the legislation necessary to carry out the role of Technical Aeronautical Engineer.
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Understanding the historic and social setting in which the graduate, in the field of Aeronautical Engineering, must carry out their activity and how it might affect the results of their activity. Possessing an aesthetic sensitivity which allows them to carry out their work in line with the successful practice of the profession.
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Possessing the skills that allow the graduate, in the scope of Aeronautical Engineering, to spatially visualise the concepts of a project and their ability to represent them graphically and turn them into a physical reality.
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Capability for design, development and management in the field of aeronautical engineering with the object,, in accordance with acquired knowledge, of aerospace vehicles, aerospace propulsion systems, aerospace materials, airport infrastructure, air navigation systems and any other system of space management, air traffic and air transport.
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Installation, exploitation and maintenance in the field of aeronautical engineering with the object, in accordance with acquired knowledge, of aerospace vehicles, aerospace propulsion systems, aerospace materials, airport facilities, air navigation systems and any other system of space management, air traffic and air transport.
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Verification and certification in the field of Aeronautical Engineering.
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Adequate and applied knowledge of the following engineering concepts: Fracture mechanics of a continuum and dynamic approaches, structural instability fatigue and aeroelastic instability.
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Adequate and applied knowledge of the following engineering concepts: Fundamentals of sustainability, maintainability and functionality of aerospace vehicles
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Adequate and applied knowledge of the following engineering concepts: Fundamentals of fluid mechanics which describe the flow in all systems to determine the distribution of pressures and forces on an aircraft
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Adequate and applied knowledge of the following engineering concepts: The physical phenomenon of flight, its qualities and control, aerodynamic forces, propulsion, performance, and stability
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Adequate and applied knowledge of the following engineering concepts: Aircraft systems and automatic flight control systems of aerospace vehicles
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Adequate and applied knowledge of the following engineering concepts: Methods of aeronautical calculation, design, and planning; the use of aerodynamic testing and of the most significant parameters in the theoretical application; the use of experimental techniques, equipment and measuring instruments particular to the field; the simulation, design, analysis and interpretation of experiments and flight operations; maintenance systems and aircraft certification
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Applied knowledge of: Aerodynamics; mechanics and thermodynamics, flight mechanics, aircraft engineering (fixed wing and rotary wing), structure theory
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Adequate and applied knowledge of the following engineering concepts: Methods of calculating, developing and installing propulsion systems; regulation and control of propulsion systems; the use of experimental techniques , equipment and measuring instruments particular to the field; fuels and lubricants used in aviation and automotive engines; numerical simulation of the most important physical and mathematical processes; maintenance and certification systems of aerospace engines
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Applied knowledge of: Internal aerodynamics; propulsion theory; performance of aeroplanes and air core reactors; propulsion systems engineering; mechanics and thermodynamics
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Adequate and applied knowledge of the following engineering concepts: Fracture mechanics of a continuum and dynamic approaches, structural instability fatigue and aeroelastic instability.
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Adequate and applied knowledge of the following engineering concepts: Fundamentals of sustainability, maintainability and functionality of aerospace systems
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Adequate and applied knowledge of the following engineering concepts: The fundamentals of fluid mechanics which describe the flow of any system and determine how aerodynamic forces and pressures are distributed.
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Adequate and applied knowledge of the following engineering concepts: The concepts and laws that govern internal combustion and their applications for rocket propulsion
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Adequate and applied knowledge of the following engineering concepts: Technological performance, techniques for optimising materials used in the aerospace sector and treatment processes for modifying their mechanical properties
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Adequate and applied knowledge of the following engineering concepts: The physical phenomenon of flight in air defence systems, its qualities, control, performance, stability and automated flight control systems
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Adequate and applied knowledge of the following engineering concepts: Calculation and development methods for defence materials and systems; the use of experimental techniques, equipment and measurement instruments particular to the field; the numerical simulation of the most significant physico-mathematical processes; techniques for inspection, quality control, fault detection; the most suitable methods and techniques for repair.
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Applied knowledge of: Aerodynamics, air defence engineering (ballistics, missiles and air systems), spacecraft propulsion, the science and technology of materials, structure theory
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Adequate and applied knowledge of the following engineering concepts: Materials used for construction; requirements and development of airport infrastructure and their environmental impact; the buildings necessary for operating and running airports
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Adequate and applied knowledge of the following engineering concepts: Specific building regulations; procedures for controlling and executing works; functioning and management of airports and air transport.
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Adequate and applied knowledge of the following engineering concepts: Methods of calculating and developing different airport building and flooring solutions; calculation systems specific to airports and their infrastructures; evaluation of technical and economic performances of aircrafts; the use of technical experiments, equipment and measurement instruments particular to the field; techniques for inspection, quality control, and fault detection; safety and control plans for airports
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Applied knowledge of: Construction; electricity; electrical engineering; electronics; flight mechanics; hydraulics; airport facilities; science and technology of materials; structure theory; maintenance and operation of airports; air transport, cartography, topography, geotechnics and meteorology
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Adequate and applied knowledge of the following engineering concepts: The basic functional elements of Air Navigation systems; requirements of on-board and ground equipment for successful operations
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Adequate and applied knowledge of the following engineering concepts: Electric and electronic equipment
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Adequate and applied knowledge of the following engineering concepts: Fundamentals of the sustainability, maintainability and operability of air navigation systems
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Adequate and applied knowledge of the following engineering concepts: Flight operations of aerospace systems; environmental impact of infrastructure; planning, design, and implementation of systems for successful air traffic management
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Adequate and applied knowledge of the following engineering concepts: Methods for calculating and developing air navigation; calculation systems specific to air navigation and their infrastructure; performance, manoeuvres and control of aircrafts; applicable
regulations; operation and management of air transport; air traffic and air travel navigation systems; aerial surveillance and communications systems.
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Applied knowledge of: Transmitters and receivers; Transmission lines and signal-emitting systems used for air navigation; Navigation systems; On-board and ground electrical installations; Flight Mechanics; Cartography; Cosmography;
Meteorology; Distribution, management and economics of air transport
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An individual and original thesis to be written, presented and defended before a university committee. The work consists of a project on technology specific to the Aerospace Engineering field; the project must be professional in nature and outline and integrate the skills acquired throughout the course.
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