|
Fundamental
|
|
Decision-making and critical reasoning.
|
|
|
|
|
|
Solving problems with initiative and in an entrepreneurial spirit.
|
|
|
Working in a multilingual and multidisciplinary environment.
|
|
|
Managing information from various sources and, where appropriate, computer tools for searching and classifying bibliographic or monomedia or multimedia information resources.
|
|
|
Understanding the ethical responsibility required to carry out professional functions.
|
|
|
Independent learning with the conviction that learning is lifelong.
|
|
|
Ability to solve mathematical problems that may arise in engineering. Ability to apply knowledge of linear algebra, geometry, differential geometry, differential and integral calculus, differential equations and partial differential equations, numerical methods, numerical algorithms, statistics and optimisation.
|
|
|
Understanding and mastery of the basic concepts of the general laws of mechanics, thermodynamics, fields and waves and electromagnetism and their application in solving engineering problems.
|
|
|
Basic knowledge on the use and programming of computers, operating systems, databases and computer programs with applications in engineering.
|
|
|
Ability to understand and apply the principles of a basic knowledge of general chemistry, organic and inorganic chemistry and their applications in engineering.
|
|
|
Capacity for spatial vision and knowledge of graphic representation techniques, both in traditional methods of metric geometry and descriptive geometry and in computer-aided design applications.
|
|
|
Adequate knowledge of the concepts of company, and the institutional and legal framework of the company. Organisation and management of companies.
|
|
|
Knowledge of applied thermodynamics and heat transfer. Basic principles and their application to solving engineering problems.
|
|
|
Knowledge of the basic principles of fluid mechanics and their application to problem-solving in the field of engineering. Calculation of pipes, channels and fluid systems.
|
|
|
Knowledge of the fundamentals of the science, technology and chemistry of materials. Understanding the relationship between microstructure, synthesis or processing and the properties of materials.
|
|
|
Knowledge and application of the principles of circuit theory, electric machines, electronics, automation and control methods.
|
|
|
Knowledge and application of the principles of the theory of machines and mechanisms and strength of materials.
|
|
|
Basic and applied knowledge of production and manufacturing systems and company organisation.
|
|
|
Basic knowledge and application of environmental technologies and sustainability.
|
|
|
Knowledge and skills to manage projects. Knowledge of the organisational structure and functions of a project office.
|
|
|
Applying knowledge of circuit theory to the calculation and design of electrical installations.
|
|
|
Applying knowledge of electromagnetism and electric machines to the calculation and design of electric machines.
|
|
|
Understanding the different energy sources and the basic principles of energy management for application in the industrial field, taking into account the related environmental aspects.
|
|
|
Applying knowledge of mechanical and materials engineering to technological concepts or developments in the industrial field.
|
|
|
Applying knowledge of thermodynamics and fluid mechanics to the design and calculation of fluid systems and machines and facilities for the production and use of energy.
|
|
|
Applying knowledge of electronics to the calculation and design of analogue, digital and power electronic systems and the use of electronic instrumentation in the industrial field.
|
|
|
Applying knowledge of automation and computer science to design industrial automation and control systems, and communication networks.
|
|
|
Applying knowledge of mechanical engineering and mechanics of materials to the design of industrial structures and constructions.
|
|
|
Ability to complete an individual project in the field of industrial technologies that distils and integrates the skills acquired in class, and which must be defended before a board of examiners.
|
|
|
Understanding and mastery of mathematical methods that broaden the basic knowledge acquired and enable the development, programming and application of analytical and numerical methods for analysing and modelling systems and processes in the field of industrial technologies.
|
|
|
Comprehension and mastery of concepts of mechanics, theory of fields and electromagnetism that broaden the basic knowledge acquired and enable the student to further explore the physical principles on which industrial technologies are based.
|
|
|
Effectively transmitting knowledge, skills, abilities, procedures, results, opinions or technical reports in the field of industrial technologies to both specialised and non-specialised audiences.
|
|
|
Advising and undertaking tasks that involve calculations, studies, reports, action plans and other similar tasks in the industrial field.
|
|
|
Analysing the processes, equipment, facilities and services studied in the industrial field, handling the technical documentation and necessary regulations.
|
|
|
Assessing the social and environmental impact of technical solutions.
|
|
|
Organising and planning within the scope of a company and of other institutions and organisations.
|
|
|
Applying the necessary legislation in the field of industrial technologies, taking into account mandatory rules and regulations.
|
|
|
Designing, calculating and testing all types of industrial machines and devices, as well as their drive, safety and control systems.
|
|
|