Students focus on one of seven areas of expertise including: MAJORS MAJORS Advanced Aerodynamics & Propulsion ∙ Advanced Aerodynamics ∙ Aeroelasticity & Flexible Aircraft - Aeroelasticity part ∙ Aeroelasticity & Flexible Aircraft - Flexible Aircraft part ∙ Advanced Aerodynamics of Turbomachinery ∙ Numerical Fluid Mechanics ∙ Aeroacoustics ∙ Physics and Modelling Turbulence ∙ Multiphase Flow and Combustion Aerospace Systems and Control ∙ Multiple-Input, Multiple-Output systems ∙ Control of flexible structures ∙ Robust and optimal control ∙ Systems identification and estimation ∙ Non-linear control ∙ Hybrid control ∙ AI methods and tools for Automatic Control ∙ Aerospace Power Systems & Architecture ∙ Aircraft & Space Actuation Systems - Preliminary Design ∙ Model & Sizing of Aircraft Air-conditioning Systems Aerospace Structures ∙ Aeroelasticity & Flexible Aircraft - Aeroelasticity part ∙ Aeroelasticity & Flexible Aircraft - Flexible Aircraft part ∙ Aerospace Structures - Advanced Structural Dynamics Part ∙ Aerospace Structures - Composite Structures in Services Part ∙ Computational Solid Mechanics ∙ Manufacturing ∙ Mechanics of materials ∙ Space Structures: spacecrafts & launchers Embedded Systems ∙ Architecture and Programming of Software Systems ∙ Real-Time Systems ∙ Model-Based System Engineering ∙ Real-Time Networks ∙ AI and Autonomous Systems ∙ Architecture, Design and Synthesis of Hardware Systems ∙ System Dependability ∙ Certification Space Systems ∙ Space environment and effects ∙ Mission analysis and orbital mechanics ∙ Space communications systems ∙ Space project: tools for simulation ∙ Space systems architecture: ground segments, satellites & sub-orbital planes ∙ Launchers architecture ∙ Satellite propulsion: chemical & electrical ∙ Satellite AOCS ∙ Launchers guidance and control ∙ Satellite electrical systems ∙ On board data handling sub-systems: functions and architectures ∙ Satellite thermal control systems ∙ Estimation and filtering Satellite Applications and NewSpace - Space environment and effects - Mission analysis and orbital mechanics - Space systems - Random signal processing and estimation - Wireless transmission techniques - Software defined-radio - Machine learning for communications - Constellations and mobile services - Satellite based navigation Systems Engineering ∙ Requirements Engineering ∙ Systems Engineering Data Technical Management ∙ Systems Modelling and Analysis ∙ Systems Dependability ∙ Systems Design and Architecture ∙ Introduction to Verification & Validation ∙ AIRBUS study case: Systems Engineering & Certification of the A350 The Master thesis is prepared either in industry or in a laboratory. It enables the student to develop deeper knowledge, understanding, capabilities and attitudes. The overall goal of the thesis is for students to demonstrate their ability to successfully take up scientific or industrial challenges MASTER THESIS MASTER THESIS / 8 /
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