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Fundamental
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Collaborate effectively in work teams, assuming responsibilities and leadership roles and contributing to collective improvement and development.
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Propose creative and innovative solutions to complex engineering situations or problems in order to respond to diverse professional and social needs.
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To act with ethics and professional responsibility in the face of social, environmental and economic challenges, taking as a reference the democratic principles and values and the Sustainable Development Goals in the definition of engineering solutions.
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Communicate effectively using verbal, oral and written, and non-verbal language, adapting to different contexts and audiences.
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Act with autonomy in learning, making informed decisions in different contexts, making judgments based on experimentation and analysis and transferring knowledge to new situations.
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Scientific-technical training for the exercise of the profession of Technical Engineer of Public Works and knowledge of the functions of consultancy, analysis, design, calculation, project, construction, maintenance, conservation and operation.
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Understanding of the multiple technical and legal constraints that arise in the construction of a public work, and ability to use proven methods and accredited technologies, in order to achieve the highest efficiency in construction while respecting the environment and protecting the safety and health of workers and users of public works.
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Knowledge, understanding and ability to apply the necessary legislation during the exercise of the profession of Technical Engineer of Public Works.
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Ability to design, inspect and direct works in their field.
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Capacity for the maintenance and conservation of water and energy resources in their field.
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Ability to carry out studies of territorial planning and environmental aspects related to infrastructures in their field.
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Capacity for the maintenance, conservation and operation of infrastructures in their field.
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Ability to carry out studies and design surface or subway water catchments in their field.
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Knowledge and ability to apply business management techniques and labor legislation.
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Knowledge of the history of civil engineering and the ability to analyze and evaluate public works in particular and construction in general.
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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 differential equations; numerical methods; numerical algorithms; statistics and optimization.
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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.
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Basic knowledge of the use and programming of computers, operating systems, databases and computer programs with engineering applications.
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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.
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Basic knowledge of geology and terrain morphology and its application in engineering related problems. Climatology.
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Adequate knowledge of the concept of the company, institutional and legal framework of the company. Business organization and management.
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Knowledge of the surveying techniques essential to obtain measurements, form plans, establish layouts, take defined geometries to the field or control movements of structures or earthworks.
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Theoretical and practical knowledge of the chemical, physical, mechanical and technological properties of the materials most commonly used in construction.
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Ability to apply knowledge of construction materials in structural systems. Knowledge of the relationship between the structure of materials and the mechanical properties derived from it.
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Ability to analyze and understand how the characteristics of structures influence their behavior. Ability to apply knowledge of the resistant performance of structures to dimension them according to existing regulations and using analytical and numerical calculation methods.
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Knowledge of geotechnics and soil and rock mechanics as well as their application in the development of studies, projects, constructions and operations where earthworks, foundations and retaining structures are required.
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Knowledge of the fundamentals of the behavior of reinforced concrete and metallic structures and ability to design, project, build and maintain this type of structures.
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Knowledge of the concepts and technical aspects related to piping systems, both in pressure and in free sheet.
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Knowledge of the basic concepts of surface and groundwater hydrology.
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Ability to analyze health and safety issues on construction sites.
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Fundamental knowledge of the electrical power system: power generation, transmission, distribution and distribution networks, as well as types of lines and conductors. Knowledge of low and high voltage regulations.
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Ability to apply methodologies for environmental impact studies and assessments.
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Knowledge of construction procedures, construction machinery and techniques of organization, measurement and valuation of works.
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Knowledge of the typology and calculation bases of precast elements and their application in manufacturing processes.
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Knowledge of the design, calculation, construction and maintenance of building works in terms of structure, finishes, installations and equipment.
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Capacity for construction and conservation of maritime works.
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Capacity for the construction and maintenance of roads, as well as for the dimensioning, design and elements that make up the basic road facilities.
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Capacity for the construction and maintenance of railroad lines with knowledge to apply the specific technical regulations and differentiating the characteristics of the rolling stock.
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Ability to apply construction procedures, construction machinery and site planning techniques.
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Capacity for the construction of geotechnical works.
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Knowledge and understanding of supply and sanitation systems, as well as their sizing, construction and maintenance.
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Knowledge and capacity to design and dimension hydraulic works and facilities, energy systems, hydroelectric developments and planning and management of surface and subway hydraulic resources.
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Knowledge and understanding of ecosystem functioning and environmental factors.
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Knowledge of urban services projects related to water distribution and sanitation.
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Knowledge and understanding of supply and sanitation systems, as well as their sizing, construction and maintenance.
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Capacity for the construction and maintenance of roads, as well as for the dimensioning, design and elements that make up the basic road facilities.
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Capacity for the construction and maintenance of railroad lines with knowledge to apply the specific technical regulations and differentiating the characteristics of the rolling stock.
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Knowledge of the regulatory framework for urban management.
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Knowledge of the influence of infrastructures on land use planning and to participate in the development of urban public space, such as water distribution, sanitation, waste management, transport system, traffic, lighting, etc.
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Knowledge of the design and operation of infrastructures for modal interchange, such as ports, airports, railway stations and transport logistics centers.
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Original exercise to be performed individually and presented and defended before a university tribunal, consisting of a project in the field of specific technologies of Civil Engineering of a professional nature in which the competences acquired in the course are synthesized and integrated.
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