RC1. Capacity to apply and integrate their knowledge to perform analysis and solve problems in new environments, not raised during the training period, and that may require collaboration and coordination with other disciplines.
RC2. Ability to plan how to solve a complex problem or project, evaluating options and alternatives and including considerations of efficiency, sustainability and social responsibility.
RC3. Capacity to integrate and contribute value in work teams for the development of projects or scientific collaborations, adequately managing work time and autonomously assuming their own tasks.
RC4. Ability, at the end of their training, to develop projects that deepen the knowledge acquired in the Master's degree or to undertake the study of new disciplines within their area, in an autonomous manner.
RC5. Ability to create advanced and innovative solutions in the optimization of industrial processes and in the generation of new products and solutions that respond to a society in constant transformation.
RCO1. Know and understand the techniques of classification, association and data dependency, and know how to identify the one that best suits the problem to be solved.
RCO2. Understand and internalize the conceptual principles related to the environmental impact of industrial processes, as well as the regulations in this field.
RCO3. To know and properly integrate the fundamental concepts of instrumentation and connectivity as well as manufacturing, applied in the digital industry.
RCO4. Understand and internalize the concepts and theoretical basis of advanced technologies used in the field of the specialty studied.
RHE1. Capacidad para exponer y comunicar resultados relevantes, tanto del propio trabajo como del de otros profesionales o investigadores en el campo de las tecnologías industriales avanzadas, así como sus implicaciones para la sociedad ante audiencias especializadas multidisciplinares e, incluso, ante el público en general.
RHE2. A commitment to integrate efficiency, sustainability, and social responsibility into the decision-making process of graduates, along with technical considerations.
RHT1. Appropriately use mathematical and computational tools to handle large amounts of information in solving engineering problems.
RHT2. Ability to design, implement, and manage a data model and integrate it into the strategic and operational decision-making processes of the organization.
RHT3. Ability to design and optimize processes and products applying sustainability criteria.
RHT4. Apply the basic tools that are used in the digital industry, both in instrumentation and connectivity as well as in manufacturing.
RHT5. Ability to project, design and calculate advanced elements or systems in the field of the specialty studied.
RHT6. Integrate all the knowledge acquired and be able to develop, coordinate and control technical activities related to the field of the specialty studied.
RHT7. Propose, manage and develop research, development and/or technological innovation projects and activities in the industrial field.
