Electromechanics

Core Courses

First Year (Common Core - Science and Technology)

Semester 1: Mathematics 1, Physics 1, Matter structure, Physics/Chemistry labs, Computer Science 1, Writing methodology

Semester 2: Mathematics 2, Physics 2, Thermodynamics, Physics/Chemistry labs, Computer Science 2, Presentation methodology

Second Year (Technological Specialization)

Semester 3: Mathematics 3, Waves and vibrations, Fundamental electronics, Fundamental electrotechnics, Probability and statistics, Computer Science 3, Electronics/Electrotechnics labs, Waves/vibrations labs

Semester 4: Linear continuous control systems (theory + lab), Combinational/sequential logic (theory + lab), Numerical methods (theory + lab), Signal theory, Electrical/electronic measurements

Third Year: Specialization

Semester 5 : Power Electronics, Electrical Machines, Mechanical Construction, Heat Transfer, Control Systems, Power Electronics Lab, Electrical Machines Lab, Control Systems Lab, Electrical Diagrams and Equipment

Semester 6: Industrial Regulation, Control of Electromechanical Drives, Sensors and Measurement Chains, Automation and Industrial Computing, Turbomachinery, End-of-Cycle Project, Regulation and Automation Lab, Control Lab, Sensors Lab

Advanced Topics

This electromechanical engineering program distinguishes itself through its balanced integration of theoretical foundations and practical applications, delivering comprehensive training at the intersection of mechanical and electrical engineering. The curriculum emphasizes hands-on competency development using state-of-the-art technological platforms including test benches, programmable automation controllers, and advanced energy conversion equipment.

Students experience substantial professional immersion through corporate internships and real industrial projects conducted in collaboration with industry partners. The program directly addresses evolving industry requirements in energy transition and digital transformation, equipping graduates to handle sophisticated systems ranging from hydraulic infrastructures to intelligent power networks.

The innovative educational approach incorporates internationally recognized professional certifications while maintaining strong connections with regional industrial ecosystems. Graduates gain access to strategic employment sectors including renewable energy, sustainable transportation, and Industry 4.0 applications, with clear pathways to technical leadership positions.

The program's unique value proposition centers on its specialized laboratory for innovative electromechanical systems and its privileged collaboration with regional energy innovation clusters. This academic-industrial synergy enables graduates to immediately fill high-demand technical roles while providing the necessary foundation for specialized graduate studies. The curriculum cultivates the increasingly scarce dual mechanical-electrical expertise while incorporating cutting-edge technological developments such as industrial process digitalization and smart manufacturing systems.