Upon completion of this course, students will have acquired and integrated multidisciplinary knowledge in the areas of Electrical Engineering, Electronic Engineer, Mechanical Engineering, and Computer Engineering in order to develop complex-function automatic control applications, taking into consideration aspects such as vibration and motion planning. They will integrate concepts of operation, interface modes, and magnetic, piezoelectric, liner, stepper, and other types of actuators. They will be able to implement complex control and feedback mechanisms in embedded programs in real time.

During this laboratory, students will analyze, design, and implement electronic control systems in real time for an application in the industrial, automotive, and communications branches in a programmable development system or in a programmable logic array. The students will generate software solutions and hardware architecutre solutions for the applications they develop, using computer tools to specify, analyze, and design solutions.

The aim is for students to apply skills and tools acquired on the different techniques and methodologies of ITR problems in a real situation.

The aim is for students to apply the skills acquired on the different techniques and methodologies of IDA problems in a real situation.

Students will plan and develop a project similar to the projects they will encounter in their careers and which integrates the knowledge acquired throughout their undergraduate degree program. They will develop their professional responsibility and methodological ability to search for, process, and use information, formulate problems , design solutions, and implement appropriate techniques. They will also work in interdisciplinary teams

The aim of this course is for students to analyze, design, and implement electronic control systems in real time for industrial, automotive, and communications applications, either in general-purpose development cards, programmable logic arrays, or on-a-chip-system design. They will generate solutions involving hardware and software architectures to run specific-application programs in a high-level language. They will also develop a specific application project for one of the application fields of real-time control systems.

Upon completion of this course, students will have learned the concepts of digital communications and they will be able to use them to analyze and design communication systems based on parameters such as error rate, bandwidth, transmission capacity, and transmission efficiency. They will also use modulation and coding techniques, as well as receiver design methods.

During this course, studentw will apply the concepts of digital signal processing and digital communications to analyze and design communication systems, based on requirement parameters and specifications.

Upon completion of this course, students will demonstrate and apply knowledge of electronic and control systems that integrate microprocessors or microcontrollers, memory, input / output ports, and communication ports, so you can analyze and design flexible architectures, interconnection between components, and programs with specific application in fields such as the automotive, industrial, aerospace, telecommunications, and control areas.