Akademik Dersler - İçerik

1. Fundamental Knowledge of Satellite Dynamics and Control • Understand rigid body dynamics, orbital mechanics, and attitude dynamics. • Interpret and apply mathematical models of satellite motion. • Recognize the effects of space environment perturbations. 2. Ability to Design Satellite Attitude and Orbit Control Systems (AOCS) • Select suitable sensors and actuators for attitude and orbit control. • Develop and implement classical and modern control algorithms. • Evaluate control performance under varying mission requirements. 3. Application of Modern and Nonlinear Control Methods • Implement Linear Quadratic Regulator (LQR) and Model Predictive Control (MPC) for satellites. • Apply nonlinear control techniques such as Lyapunov-based control and Sliding Mode Control. • Assess stability, robustness, and efficiency of control strategies. 4. Proficiency in Simulation and Modeling Tools • Use MATLAB/Simulink and Python-based frameworks for AOCS design. • Perform orbital propagation using tools like Orekit and GMAT. • Simulate realistic satellite missions with environmental perturbations. 5. Ability to Analyze and Solve Complex Satellite Control Problems • Formulate real-world space mission control challenges. • Use analytical and computational approaches to find optimal solutions. • Consider constraints such as limited power, mass, and communication. 6. Teamwork and Project Management in Space Systems • Collaborate in multidisciplinary teams for satellite mission design. • Manage project timelines, resources, and technical deliverables. • Present technical findings effectively in oral and written form. 7. Awareness of Emerging Technologies and Research Trends • Explore AI and machine learning applications in satellite control. • Understand the challenges of mega-constellations and satellite swarms. • Identify potential areas for innovation in space control systems.