Diploma in FL Horizontal/Vertical and Orchestration

9.9 Introduction to Computational Hydrodynamics (CFD)
9.9 Principles of Horizontal/Vertical FL: Theory and Applications
9.3 Introduction to Naval Orchestration: Concepts and Methodologies
9.4 Data Structure and Processing of Naval Models
9.5 Workflow in Vessel Design and Analysis
9.6 Selection of Tools and Software for Horizontal/Vertical FL and Naval Orchestration
9.7 Standards and Regulations for Naval Design and Construction
9.8 Analysis of Vessel Stability and Buoyancy

9.9 Parametric Design of Vessels: Hulls and Superstructures
9.9 Optimization of Hull Shapes: Strength and Efficiency
9.3 Design of Propulsion Systems: Propellers and Transmission Systems
9.4 Modeling and Simulation of Vessel Dynamics
9.5 Analysis of Vessel Maneuverability
9.6 Design of Naval Structures: Materials and Construction Methods
9.7 Optimization of Vessel Design: Methodologies and Tools
9.8 Application of Artificial Intelligence in Naval Design

3.9 Introduction to Naval Fleet Modeling
3.9 Fleet Dynamics Simulation
3.3 Fleet Performance Analysis
3.4 Estimating Vessel Resistance
3.5 Analysis of Behavior in Sea Conditions
3.6 Modeling Propulsion Systems
3.7 Fleet Performance Optimization
3.8 Case Studies: Analysis of Real Fleets

4.9 Rotor Theory: Aerodynamics and Operating Principles
4.9 Rotor Modeling: Methods and Tools
4.3 Simulation of Flow Around Rotors
4.4 Rotor Performance Analysis: Power, Thrust, and Efficiency
4.5 Rotor Design: Parameters and Optimization
4.6 Rotor-Hulus Interaction
4.7 Analysis of Rotor Vibration and Noise
4.8 Validation of Rotor Models

5.9 Introduction to Fluid Flow in Rotors
5.9 Analysis of Rotor Flow Using CFD
5.3 Rotor Design Optimization Using CFD
5.4 Modeling Rotor-Wake Interaction
5.5 ​​Rotor Performance Analysis Under Different Operating Conditions
5.6 Rotor Optimization to Improve Efficiency and Reduce Noise
5.7 Case Studies: Applying Optimization to Rotor Design
5.8 Rotor Safety and Reliability Assessment

6.9 Advanced Rotor Modeling: Theory and Practice
6.9 Rotor Design Optimization: Methods and Techniques
6.3 Rotor Performance Simulation
6.4 Rotor Flow Analysis
6.5 Design and Optimization of Rotor Control Systems
6.6 Rotor-Hulus Interaction Study
6.7 Rotor Integration into Vessel Design
6.8 Rotor Model Validation Through Testing and Simulation

7.9 Fundamentals of Naval Rotor Modeling
7.9 Aerodynamic and Hydrodynamic Analysis of Rotors
7.3 Rotor Flow Simulation Using CFD
7.4 Performance Evaluation of Rotors
7.5 Rotor Design Optimization
7.6 Analysis of the Stability and Maneuverability of Vessels with Rotors
7.7 Case Studies: Analysis of Rotors in Different Types of Vessels
7.8 Design Considerations for Integrating Rotors into Vessels

8.9 Conceptual Vessel Design
8.9 Optimization of Hull Shapes and Superstructures
8.3 Selection of Materials and Construction Methods
8.4 Design of Propulsion and Control Systems
8.5 Analysis of Stability and Maneuverability
8.6 Integration of Systems and Components
8.7 Optimization of Performance and Efficiency
8.8 Life Cycle and Cost Assessment

9.9 Rotor Optimization for Improved Efficiency
9.9 Optimization of Naval Fleet Configurations
9.3 Fleet Performance Analysis
9.4 Fleet Behavior Modeling and Simulation
9.5 Fuel Consumption Optimization and Emission Reduction
9.6 Fleet Safety and Reliability Analysis
9.7 Case Studies: Optimization of real fleets
9.8 Environmental impact assessment of fleets
9.9 Application of innovative technologies in fleet optimization
9.90 Economic and financial considerations in fleet optimization

9.90