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Results


These are the outcomes that students acquire through this program: the outcomes (common to all UPV graduates), and the general and specific outcomes of the program, here called "fundamental".

UPV generic Where is evaluated?
Social and environmental commitment
To act with ethics and professional responsibility in the face of social, environmental and economic challenges, taking democratic principles and values and the Sustainable Development Goals as a reference.
Innovation and creativity
Propose creative and innovative solutions to complex situations or problems, specific to the field of knowledge, in order to meet diverse professional and social needs.
Teamwork and leadership
Collaborate effectively in work teams, assuming responsibilities and leadership roles and contributing to collective improvement and development.
Effective communication
Communicate effectively, both orally and in writing, adapting to the characteristics of the situation and the audience.
Responsibility and decision-making
Act autonomously in learning, making informed decisions in different contexts, making judgements based on experimentation and analysis and transferring knowledge to new situations.

Fundamental
Ability to solve problems with initiative, decision making, creativity, critical reasoning and to communicate and transmit knowledge, skills and abilities in the field of Industrial Engineering.
Knowledge to carry out measurements, calculations, appraisals, valuations, appraisals, surveys, studies, reports, work plans and other similar work.
Ability to handle specifications, regulations and mandatory standards.
Ability to analyze and assess the social and environmental impact of technical solutions.
Ability to apply quality principles and methods.
Organizational and planning skills within the company and other institutions and organizations.
Ability to work in a multilingual and multidisciplinary environment.
Knowledge, understanding and ability to apply the necessary legislation in the exercise of the profession of Industrial Technical Engineer.
Possess a social-historical culture and aesthetic sensibility.
Ability to apply knowledge on occupational health and safety, occupational risk prevention and machine safety, according to current regulations on passive and active fire protection, and noise pollution aspects
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 and partial derivative equations; numerical methods; numerical algorithms; statistics and optimization.
Understanding and mastery of the basic concepts of the general laws of mechanics, thermodynamics, fields and waves and electromagnetism and their application to solve engineering problems.
Basic knowledge of the use and programming of computers, operating systems, databases and computer programs with engineering applications.
Ability to understand and apply the basic knowledge principles of general chemistry, organic and inorganic chemistry and their applications in engineering.
Capacity for spatial vision and knowledge of graphic representation techniques, both by traditional methods of metric geometry and descriptive geometry, as well as by means of computer-aided design applications.
Adequate knowledge of the concept of the company, institutional and legal framework of the company. Business organization and management.
Knowledge of applied thermodynamics and heat transfer. Basic principles and their application to engineering problem solving.
Knowledge of the basic principles of fluid mechanics and their application to solving problems in the field of engineering
Knowledge of the fundamentals of materials science, technology and chemistry. Understand the relationship between microstructure, synthesis or processing and material properties.
Knowledge and use of the principles of circuit theory and electrical machines.
Knowledge of the fundamentals of electronics.
Knowledge of the fundamentals of automation and control methods.
Knowledge of the principles of machine and mechanism theory.
Knowledge and use of the principles of strength of materials.
Basic knowledge of production and manufacturing systems.
Basic knowledge and application of environmental technologies and sustainability.
Applied knowledge of business organization.
Knowledge and skills to organize and manage projects. Know the organizational structure and functions of a project office.
Applied knowledge of electrical engineering.
Knowledge of the fundamentals and applications of analog electronics.
Knowledge of the fundamentals and applications of digital electronics and microprocessors.
Applied knowledge of power electronics.
Applied knowledge of electronic instrumentation.
Ability to design analog, digital and power electronic systems.
Knowledge and ability for systems modeling and simulation.
Knowledge of automatic regulation and control techniques and their application to industrial automation.
Knowledge of principles and applications of robotic systems.
Applied knowledge of industrial computing and communications.
Ability to design industrial automation and control systems.
Ability to draft, sign and develop projects in the field of industrial engineering for the construction, renovation, repair, conservation, demolition, manufacture, installation, assembly or operation of: structures, mechanical equipment, energy installations, electrical and electronic installations, industrial installations and plants, and manufacturing and automation processes.
Ability to manage the activities involved in the engineering projects described in competency 61.
Knowledge in basic and technological subjects, which enables them to learn new methods and theories, and gives them the versatility to adapt to new situations.