PhD in Engineering Sciences – Specialization in Electrical Engineering
GEETS * Doctoral School – University of Toulouse 3 – 2020
As part of my PhD, I complemented my scientific training through international summer schools specialized in power electronics, reliability, and electrical systems. These programs enabled me to deepen my understanding of physical failure mechanisms, lifetime modeling methods, and the systemic challenges associated with modern electrical networks.
Power device reliability:
– Lifetime estimation of active and passive components
– MTBF calculation methods and their application limits
– Thermo-mechanical aging mechanisms
– Robustness of power semiconductors
– Multi-physics constraints and failure mechanisms
Converter reliability and operational safety:
– Fault diagnosis and prognostics
– Converter topology protection and reconfiguration strategies
– Reliability approaches applied to static converters
– Availability and service continuity analysis
Power electronics & low-loss switching:
– Design of low-loss power circuits
– Soft-switching techniques
– Multi-phase architectures for industrial applications
– Advanced integration of drive systems
Electrical grids & energy systems:
– Role of power electronics in future power grids
– DC grids and hybrid architectures
– Smart grids and international standards
– Device sensitivity to grid disturbances
– Renewable energy integration
Industrial approach & energy transition:
– Converter–grid interaction
– Reliability in critical applications
– Industrial feedback and experience
– Strategic challenges for the energy transition
These programs strengthened my expertise in advanced power electronics, reliability modeling, and converter integration within complex energy systems, with a scientific, industrial, and systemic perspective.
* French abbreviation meaning : Electrical Engineering, Electronics, Telecommunications and Health: from system to nanosystem
Master Degree in Mechatronics
CNAM Poitou-Charentes – 2016
My master degree at CNAM enabled me to develop multidisciplinary expertise focused on the design, modeling, and optimization of complex industrial systems. The program integrates technological, economic, organizational, and human dimensions.
Electrical engineering & power electronics:
– Design and sizing of industrial electrical installations
– Dynamic modeling of electrical machines
– Machine–drive association and actuator control
– Power converters and energy management
– Electrical safety and standards compliance
Electronics & signal processing:
– Design of analog and digital functions
– Programmable logic and sequential system synthesis
– Time and frequency domain signal analysis
– Sampling, digitization, and analog/digital filtering
– Sensor data analysis and processing
Control, automation & industrial computing:
– Identification and modeling of industrial processes
– Static and dynamic performance analysis
– Analog and digital control (PID)
– Simulation and modeling of control systems
– Programming of control-command systems
– Industrial architectures and supervision (HMI)
Mechanics & mechanical systems:
– Statics, kinematics, and dynamics of mechanisms
– Power transmission chain modeling
– Design of complex mechanical systems
– Integration of deformation and dynamic effects
– CAD tools and mechanical simulation
Thermal engineering & fluid mechanics:
– Modeling of flows and hydraulic systems
– Heat transfer and thermal sizing
– Integration of thermo-mechanical constraints
– Selection and sizing of fluid components
Instrumentation & data acquisition:
– Industrial sensor and actuator technologies
– Acquisition chain design and signal conditioning
– Experimental validation and physical measurements
– Electromagnetic compatibility
Mechatronics & embedded systems:
– Multi-technology system design
– Axis control and industrial robotics
– Multi-physics modeling and optimization
– Embedded architectures (FPGA, SoC)
– Wired and wireless industrial communication
– Eco-design and product ergonomics
Industrial design & project management:
– Functional analysis and system engineering (V-model)
– Technical documentation and specifications writing
– Product testing, validation, and certification
– Project planning, budgeting, and cost analysis
– Risk management and continuous improvement
– Technical team management
– Technical communication and technology monitoring
This program enabled me to develop a versatile engineering profile, capable of designing, modeling, controlling, and optimizing complex mechatronic systems while integrating technical, economic, environmental, and human constraints.
University Diploma of Technology in Electrical Engineering and Industrial Computing
Institute of Technology of Poitiers – 2013
During my bachelor degree at the IUT of Poitiers, I developed a solid scientific and technical foundation focused on the design, integration, and operation of electrical, electronic, and automated systems. The curriculum combined theoretical courses, intensive laboratory work, and industrial projects.
Electronics:
– Circuit analysis and design (Kirchhoff, Thévenin/Norton)
– Operational amplifiers, active filters, and frequency analysis
– BJT and MOSFET transistors (biasing, amplification, switching)
– Combinational and sequential logic (flip-flops, registers, counters)
– Basics of programmable logic
– Electronic board design and simulation
Energy & electrical engineering:
– Energy conversion: rectifiers, inverters, DC/DC converters
– Power regulation and industrial power supplies
– Electrical machines (asynchronous, synchronous, stepper motors)
– Motor control and variable speed drives
– Electrical installation sizing
Automation & control:
– Functional analysis and GRAFCET
– Industrial PLC programming
– Dynamic system modeling
– PID controllers and industrial regulation
– Stability analysis (Bode, Nyquist)
– Industrial process automation
Industrial computing & embedded systems:
– Embedded C programming on microcontrollers
– Interrupt management, timers, ADC/DAC
– Sensor data acquisition
– Industrial communication protocols (Modbus, CAN, Ethernet)
– Supervision and human-machine interfaces
Scientific tools:
– Metrology and measurement uncertainty analysis
– AC regimes and complex numbers
– Laplace transform and linear systems
– Simulation and modeling (Matlab, Scilab, LTspice)
The projects completed during the program allowed me to apply these skills to practical systems: functional electronic board design, motor control, industrial automation, and embedded system development.
This program provided me with a comprehensive and coherent vision of electrotechnical and electronic systems, combining scientific rigor, experimentation, and an industrial approach.
Scientific Baccalaureate – Specialization in Engineering Sciences
Lycée Sadi Carnot Jean Bertin – 2011
Scientific curriculum focused on mathematics, physics, and engineering sciences, with a technological approach centered on the analysis and understanding of mechanical, electrical, and automated systems.