Specialities

The AOS course focuses on learning and optimization aspects for applications in interoperable autonomous technology systems, so-called systems of systems. Such systems are, for example, intelligent road vehicles communicating with each other or with the infrastructure of an intelligent transport system, aerial mini-drones or sensor networks that exchange information in real time. The systems studied implement, among other things, learning, decision and action capabilities while interacting with their environment and other systems. They must also be able to cope with many sources of uncertainty that can affect their performance and consequently their operation. The course is integrated into the training component of the Laboratory of Excellence (Labex) Master of System of Systems.

You can find more details about AOS on the UTC website

The course ARS is interested in the software aspects of autonomous technological systems in mutual interaction, called system systems. Such systems are, for example, intelligent road vehicles communicating with each other or with the infrastructure of an intelligent transport system, aerial mini-drones or sensor networks that exchange information in real time. The systems studied generally use perception, communication, learning, decision and action abilities while interacting with their environment and their peers. They must also be able to cope with many sources of uncertainty that can affect their performance and, as a result, the operation of the system. The course is part of the training component of the Laboratory of Excellence (Labex) Master of System System.

You can find more details about ARS on the UTC website

The Biomechanics and Bioengineering (BMI) course focuses on health technologies from the perspective of the system approach. Biomechanical engineering and bioengineering are based on multiscale but also multiphysical approaches. Future health devices will combine miniaturized electronic elements, with micro- or nano-sized mechanical elements and biological elements. This multidisciplinary, multi-scale and multiphysical approach, in technological and scientific break with the current tools of the Health, is the crucible of this specific formation.

You can find more details about BMI on the UTC website

At the crossroads of mechanical testing and numerical simulation, the aim of the complex structures and mechanical systems (SMC) course is to train specialists in understanding the mechanical behavior of materials and numerical simulation, able to design, validate, new materials, structures and mechanical systems and optimize their performance. Emphasis is placed on the ability to conduct and integrate an experimental joint approach, modeling and numerical simulation.

You can find more details about SMC on the UTC website

Mechatronics is defined as the synergistic and systemic combination of mechanics, electronics and computing. The aim of the mechatronic systems course (SMT) is to train future managers in this field of multidisciplinary engineering, particularly in the design and control of complex mechatronic systems ranging from the microsystem to the vehicle. The training offered is transversal to the fields of mechanics, electronics and informatics and focuses on the system aspect, which offers a great potential for graduates. This course is aimed both at mechatronics specialists seeking to reinforce their knowledge and at mechanics wishing to have an opening towards mechatronics. The course is part of the training component of the Laboratory of Excellence (Labex) "Master of Systems of Systems".

You can find more details about SMT on the UTC website