Diploma in 1D/3D Coupling and Co-Sim Orchestration
Sobre nuestro Diploma in 1D/3D Coupling and Co-Sim Orchestration
The Diploma in 1D/3D Coupling and Co-Sim Orchestration explores the use of advanced tools in the simulation of complex systems, focusing on the coupling of 1D and 3D models to optimize the design and analysis of systems in various engineering disciplines. It centers on simulation integration, data management, and workflow automation through co-simulation orchestration. The program addresses the application of methodologies for transient analysis, multi-domain optimization, and system performance evaluation, crucial for the development of innovative products. The program provides hands-on experience using simulation platforms and tools, with an emphasis on model validation, complexity management, and results interpretation. It delves into topics such as functional coupling, data exchange, and optimizing communication between different modules and solvers. This training prepares professionals for roles such as simulation engineers, systems analysts, and modeling specialists, strengthening employability in industries such as automotive, aerospace, and energy. Target keywords (natural occurrences in the text): systems simulation, 1D/3D coupling, co-simulation, orchestration, transient analysis, optimization, modeling, data management.
Diploma in 1D/3D Coupling and Co-Sim Orchestration
- Modalidad: Online
- Duración: 8 meses
- Horas: 900 H
- Idioma: ES / EN
- Créditos: 60 ECTS
- Fecha de matrÃcula: 19-06-2026
- Fecha de inicio: 30-07-2026
- Plazas disponibles: 3
1.449 $
Competencias y resultados
Qué aprenderás
1. Proficiency in 1D/3D modeling and Co-Sims orchestration for naval dockings
- Advanced Modeling and Simulation: Master 1D/3D modeling of critical naval components, including structures and complete systems. Learn to build accurate models to simulate vessel behavior under various operating conditions.
- Co-Sim Orchestration: Develop the ability to integrate models from different disciplines (hydrodynamics, aeroelasticity, structural engineering) through co-simulations.
- Joints: Analyze and optimize mechanical and structural joints.
- Bonded Joints: Dimension and evaluate the integrity of bonded joints.
This will allow you to analyze the overall performance of naval systems.
Structural and Dynamic Analysis: Delve into the analysis of key phenomena such as:
Flap-Lag-Torsion: Understand and simulate the dynamic behavior of rotating blades, such as those of propellers and rotors.
Whirl Flutter: Identify and analyze the phenomenon of vibrational instability in rotating systems.
Fatigue: Evaluate the service life of naval components under cyclic loads and variable operating conditions.
Component Design and Sizing: Acquire skills to size components using finite element analysis (FEA):
Composites: Design and size composite material structures, optimizing strength and weight.
- Damage Tolerance: Implement strategies to evaluate a structure’s capacity to withstand damage and failure.
- NDT (UT/RT/Thermography): Familiarize yourself with non-destructive testing techniques such as ultrasonic testing (UT), radiography (RT), and thermography to inspect and evaluate the integrity of components.
2. Advanced Modeling and Joint Simulation of 1D/3D Naval Docking Systems
2. Advanced Modeling and Joint Simulation of 1D/3D Naval Docking Systems
- Master the analysis of complex docking systems: flap-lag-torsion, essential for stability and maneuverability; whirl flutter, critical for structural integrity during rotation; and the study of fatigue, fundamental for component durability.
Apply finite element (FE) modeling techniques for the precise dimensioning of laminates in composite materials, optimizing strength and weight.
Evaluate and design joints, including bonded joints, ensuring load transfer and structural integrity.
Integrate damage tolerance methodologies for component life management and safety.
Implement advanced non-destructive testing (NDT) techniques, such as ultrasonic testing (UT), radiography (RT), and thermography, for early defect detection and integrity assessment.
3. Comprehensive user-oriented design and validation (from modeling to manufacturing)
You will learn to integrate the entire product development process, from initial model conception to final validation, applying user-centered methodologies. You will develop skills in parametric design, ergonomics, simulation, sustainable materials, 3D visualization, and manufacturing management, ensuring efficient, safe solutions that meet current industry standards.
4. Analysis and optimization of naval docking systems using 1D/3D modeling and co-simulation
- Model and simulate complex naval couplings, including vibration mode analysis and dynamic stability.
- Apply 1D/3D modeling and co-simulation techniques to evaluate the structural behavior of couplings under different loading and operating conditions.
- Analyze flap-lag-torsion, whirl flutter, and fatigue couplings.
- Optimize coupling design to improve performance, durability, and service life, considering factors such as weight, strength, and efficiency.
- Dimension laminates in composites, joints, and bonded joints with FE.
- Evaluate and mitigate the risks associated with coupling failure, including identifying critical points and implementing preventive measures.
- Implement damage tolerance and NDT (UT/RT/thermography).
Use specialized software for the analysis and optimization of naval couplings, interpreting the results and making data-driven design decisions.
Understand the regulations and standards relevant to the design and operation of naval couplings, ensuring compliance with safety and performance requirements.
5. Rotor Modeling: Performance Optimization in Naval Simulations
- Explore the complexities of rotor analysis, including the evaluation of flap-lag-torsion couplings, crucial for understanding structural dynamics.
- Master the simulation of critical phenomena such as whirl flutter, essential for safety, and analyze fatigue, a key factor in rotor durability.
- Delve into the design and dimensioning of laminar structures using composites, applying finite element (FE) analysis to joints and bonded joints.
- Study the application of advanced techniques to ensure structural integrity, including the implementation of damage tolerance methodologies.
- Become familiar with non-destructive testing (NDT) methods such as UT/RT/thermography, for the inspection and evaluation of rotors.
6. Rotor modeling and simulation for naval design optimization [The text abruptly shifts to a seemingly unrelated topic:]
You will learn to integrate the entire product development process, from initial model conception to final validation, applying user-centered methodologies. You will develop skills in parametric design, ergonomics, simulation, sustainable materials, 3D visualization, and manufacturing management, ensuring efficient, safe solutions that meet current industry standards.
Para quien va dirigido nuestro:
Diploma in 1D/3D Coupling and Co-Sim Orchestration
- Graduates in Aerospace Engineering, Mechanical Engineering, Industrial Engineering, Automation Engineering, or related fields.
- Professionals from OEM rotorcraft/eVTOL, MRO, consulting, technology centers.
- Flight Testing, certification, avionics, control, and dynamics seeking specialization.
- Regulators/authorities and UAM/eVTOL professionals requiring compliance skills.
Recommended qualifications: foundation in aerodynamics, control, and structures; ES/EN B2+/C1. We offer bridging tracks if needed.
- Standards-driven curriculum: you will work with CS-27/CS-29, DO-160, DO-178C/DO-254, ARP4754A/ARP4761, ADS-33E-PRF from the first module.
- Accreditable laboratories (EN ISO/IEC 17025) with rotor bench, EMC/Lightning pre-compliance, HIL/SIL, vibrations/acoustics.
- Evidence-oriented TFM: safety case, test plan, compliance dossierand operational limits.
- Mentored by industry: teachers with experience in rotorcraft, tiltrotor, eVTOL/UAM and flight test.
- Flexible modality (hybrid/online), international cohorts and support from SEIUM Career Services.
- Ethics and security: safety-by-design approach, cyber-OT, DIH and compliance as pillars.
Module 1 — 1D/3D Modeling and Co-Sims in Naval Docking
1.1 Introduction to 1D/3D Modeling in Naval Design
1.2 Fundamentals of Co-Simulation for Naval Docking
1.3 Modeling the Hydrodynamics of Ships and Structures
1.4 Modeling Naval Propulsion Systems
1.5 Integrating 1D and 3D Models in Co-Simulations
1.6 Simulation of Naval Dockings: Case Studies
1.7 Analysis of Results and Design Optimization
1.8 Tools and Software for Naval Modeling and Simulation
1.9 Validation and Verification of Models
1.10 Advanced Applications and Future Trends
2.2 Modeling of 2D/3D Naval Propulsion Systems for Docking
2.2 Advanced Co-simulation Techniques in Naval Docking
2.3 Integration of 2D and 3D Models in Naval Simulations
2.4 Fluid-Structure Interaction Analysis in Docking
2.5 Simulation of Maneuvering and Dynamic Naval Behavior
2.6 Modeling of Control Systems in Naval Docking
2.7 Validation and Verification of Docking Models
2.8 Performance Optimization in 2D/3D Naval Simulations
2.9 Sensitivity and Uncertainty Analysis in Docking Models
2.20 Practical Applications and Case Studies in Naval Docking
3.3 Introduction to Rotor Modeling for Naval Design
3.2 Fundamentals of Rotor Hydrodynamics
3.3 Numerical Rotor Modeling: Methods and Tools
3.4 Rotor Design: Concepts and Principles
3.5 Rotor Simulation: Performance Analysis
3.6 Rotor Design Optimization
3.7 Practical Applications: Rotor Selection and Configuration
3.8 Rotor-Hull Interaction Effects
3.9 Cavitation and Noise Analysis in Rotors
3.30 Case Studies: Rotor Design and Simulation in Practice
3.30
4.4 Introduction to 4D/3D Modeling for Naval Systems
4.2 Modeling Tools and Software
4.3 Co-Sim Orchestration: Principles and Applications
4.4 Simulation of Naval Dockings: Practical Examples
4.5 Results Analysis and Basic Optimization
4.6 Design of Experiments and Sensitivity Analysis
4.7 Case Studies: Real-World Applications in Naval Engineering
4.8 Integration of 4D and 3D Models
4.9 Efficient Workflows for Simulation
4.40 Introduction to Model Validation and Verification
2.4 Advanced 4D/3D Modeling of Naval Systems
2.2 Joint Simulation Techniques: Complex Dockings
2.3 Analysis of Different Simulation Scenarios
2.4 Modeling of Specific Components: Propellers, Rudders, etc.
2.5 Energy Efficiency Optimization
2.6 Model Validation and Calibration
2.7 Co-Simulation for Dynamic Scenarios
2.8 Wave and Marine Condition Simulation
2.9 Stability and Maneuverability Analysis
2.40 Applications of Advanced Simulation
3.4 Introduction to Naval Rotor Design
3.2 Principles of Rotor Aerodynamics and Hydrodynamics
3.3 Rotor Modeling: Methods and Software
3.4 Rotor Performance Simulation: Thrust, Torque, and Efficiency
3.5 Rotor Geometry Design and Optimization
3.6 Cavitation Analysis
3.7 Influence of the Rotor Wake on Hull Design
3.8 Rotor-Hulch Interaction Simulation
3.9 Case Studies: Successful Rotor Designs
3.40 Future Trends in Rotor Design
4.4 4D/3D Modeling and Simulation for Naval Docking Systems
4.2 Software and Tool Selection
4.3 Design Strategies Co-Simulation for Optimization
4.4 Performance Optimization: Efficiency and Consumption
4.5 Propulsion Optimization
4.6 Systems Integration: Hull, Propulsion, and Steering
4.7 Sensitivity Analysis and Design of Experiments
4.8 Multi-Objective Optimization
4.9 Cost and Life Cycle Analysis
4.40 Case Studies: Practical Application in Naval Design
5.4 Fundamentals of Rotor Modeling
5.2 Simulation Software and Methods
5.3 Rotor Performance Analysis in Simulations
5.4 Performance Optimization: Efficiency and Cavitation
5.5 ​​Influence of Geometry on Performance
5.6 Simulation of Different Operating Conditions
5.7 Design of Experiments in Rotor Simulation
5.8 Rotor Wake Analysis
5.9 Rotor-Hulch Interaction Optimization
5.40 Case Studies: Performance Analysis
6.4 Introduction to Naval Rotor Modeling
6.2 Simulation Software and Tools
6.3 Rotor Modeling: Methods and Techniques
6.4 Performance Simulation: Thrust, Torque, and Efficiency
6.5 Rotor Design Optimization
6.6 Cavitation Analysis
6.7 Rotor-Hull Interaction Modeling
6.8 Influence of Hull Design on Performance
6.9 Case Studies: Design Examples
6.40 Rotor Model Validation and Verification
7.4 Optimization Principles in Naval Design
7.2 Optimization Methodologies for Rotors
7.3 Hull Design Optimization
7.4 Propulsion Optimization
7.5 Energy Efficiency Optimization
7.6 Life Cycle Considerations
7.7 Sensitivity Analysis and Design of Experiments
7.8 Multi-Objective Optimization
7.9 Case Studies: Optimized Ship Design
7.40 Future Trends in Naval Optimization
8.4 Introduction to Rotor Modeling and Simulation
8.2 Software and Tool Selection
8.3 Simulation Methods for Rotors
8.4 Performance Analysis Thrust, Torque, and Efficiency
8.5 Rotor Design and Optimization
8.6 Cavitation Modeling
8.7 Rotor-Hull Interaction Simulation
8.8 Rotor Wake Analysis
8.9 Case Studies: Applications in Naval Design
8.40 Comprehensive Ship Design and Optimization
8.5 Rotor Design and Optimization
5.5 Introduction to 5D Modeling of Naval Systems
5.5 3D Modeling of Naval Structures: Hulls and Components
5.3 Integration of 5D/3D Models in Naval Simulations
5.4 Principles of Computational Fluid Dynamics (CFD) Applied to Navigation
5.5 ​​Tools and Software for 5D/3D Naval Modeling
5.6 Practical Applications: Preliminary Design and Performance Analysis
5.5 Fundamentals of Co-simulation in Naval Docking Systems
5.5 Interconnection of 5D and 3D Models
5.3 Advanced Co-simulation Techniques
5.4 Simulation of Complex Fluid Dynamic Interactions
5.5 Optimization Strategies in Co-simulation
5.6 Practical Applications: Stability and Maneuverability Analysis
3.5 Fundamentals of Naval Rotor Design
3.5 Detailed Modeling of Propellers and Propulsion Systems
3.3 Rotor Performance Simulation: Thrust, Torque, and Efficiency
3.4 Cavitation Analysis and Vibrations
3.5 Selection of materials and manufacturing processes for rotors
3.6 Practical applications: Rotor design optimization
4.5 Performance analysis of propulsion systems using 5D/3D modeling
4.5 Optimization of energy efficiency in marine couplings
4.3 Hull-propeller interaction analysis
4.4 Study of different propulsion configurations
4.5 Implementation of optimization strategies
4.6 Practical applications: Reduction of consumption and improvement of efficiency
5.5 Rotor theory: Fundamental principles and concepts
5.5 Rotor modeling: Simulation methods and tools
5.3 Simulation of rotor performance under different operating conditions
5.4 Analysis of the influence of rotor design on efficiency and performance
5.5 Optimization of rotor design for marine applications
5.6 Practical applications: Evaluation and improvement of rotor performance
6.5 Rotor design and modeling: Methodologies and tools
6.5 Simulation of flows around rotors: CFD and other methods Panel
6.3 Rotor Performance Analysis: Thrust, Torque, and Efficiency
6.4 Cavitation and Vibration Assessment
6.5 Rotor Design Optimization: Strategies and Techniques
6.6 Practical Applications: Design and Analysis of Rotors for Specific Vessels
7.5 Optimization Strategies in Naval Design
7.5 Rotor Performance Optimization through Modeling and Simulation
7.3 Integration of Simulation Data into the Design Process
7.4 Design of Experiments and Sensitivity Analysis
7.5 Cost-Benefit and Life Cycle Analysis
7.6 Practical Applications: Naval Design Optimization Case Studies
8.5 Simulation Principles in Naval Design
8.5 Rotor Modeling for Design Simulations
8.3 Rotor Performance Analysis in Different Scenarios
8.4 Rotor Design Optimization for Efficiency and Maneuverability
8.5 Rotor-Hulus Interaction Simulation
8.6 Practical Applications: Using Simulations in Naval Design
6.6 Introduction to 6D/3D Naval Modeling
6.2 Regulations and Standards in Naval Design
6.3 Principles of Naval Hydrodynamics and Aerodynamics
6.4 Naval Modeling Software and Tools
6.5 Hull and Propulsion System Modeling
6.6 Introduction to Naval Systems Simulation
6.7 Application of Regulations in Design and Modeling
6.8 Case Studies: Examples of Regulated Naval Design
2.6 Fundamentals of Co-Sims and Naval Coupling
2.2 Interaction between 6D and 3D Systems in Simulations
2.3 Modeling of Propulsion and Control Systems
2.4 Coupling of Fluid and Structural Models
2.5 Simulation of Naval Maneuvers
2.6 Performance and Energy Efficiency Analysis
2.7 Co-simulation for Design Optimization
2.8 Practical Cases of 6D/3D Coupling
3.6 Rotor Design Principles for Naval Applications
3.2 Rotor Theory and Aerodynamics
3.3 Rotor Modeling Using CFD
3.4 Blade Design and Airfoil Selection
3.5 Rotor Performance Simulation Under Different Conditions
3.6 Cavitation and Vibration Analysis
3.7 Rotor Design Optimization
3.8 Case Studies: Rotor Design and Analysis
4.6 Drag Analysis in 6D/3D Models
4.2 Wake and Flow Simulation Around the Hull
4.3 Co-simulation for Hull Design Optimization
4.4 Propulsion System Performance Analysis
4.5 Energy Efficiency Optimization and Emission Reduction
4.6 Maneuverability and Stability Analysis
4.7 Marine Dock Optimization Methodology
4.8 Practical Applications of Analysis and Optimization
5.6 Rotor Design Optimization for Efficiency
5.2 Rotor Performance Analysis Under Different Conditions
5.3 Cavitation and Erosion Simulation
5.4 Material Selection and Manufacturing Processes
5.5 Rotor Geometry Optimization The Blade
5.6 Rotor Performance Evaluation in Different Operating Scenarios
5.7 CFD-Based Optimization Methodology
5.8 Practical Cases of Rotor Optimization
6.6 Hull and Propulsion System Modeling
6.2 Hull and Propulsion System Performance Simulation
6.3 Rotor Modeling and Performance Analysis
6.4 Flow Simulation Around the Hull and Rotor
6.5 Naval Design Optimization Through Simulation
6.6 Maneuverability and Stability Analysis
6.7 Design Evaluation Under Sea Conditions
6.8 Systems Integration and Overall Design
6.9 Case Study: Complete Naval Design
6.60 Cost-Benefit Analysis of Naval Design
7.6 Hull Shape Optimization
7.2 Propulsion System Design and Optimization
7.3 Rotor Design Optimization for Efficiency
7.4 Vessel Performance Analysis Under Different Conditions
7.5 Naval Design Evaluation Through Simulation
7.6 Stability and Maneuverability Analysis
7.7 Design Optimization Methodologies
7.8 Practical Applications of Naval Design Optimization
8.6 Rotor Performance Simulation
8.2 Rotor Performance Analysis Under Different Conditions
8.3 Rotor Design Optimization
8.4 Rotor Modeling in Naval Design
8.5 Flow Simulation Around the Hull and Rotor
8.6 Rotor Integration into the Propulsion System Design
8.7 Energy Efficiency Analysis
8.8 Case Studies: Rotor Design and Simulation
8.6
7.7 Introduction to 7D and 3D Modeling in Naval Design
7.2 Principles of Hydrodynamics and Aerodynamics Applied to Ships
7.3 Naval Modeling Tools and Software
7.4 Workflows for Creating 7D and 3D Models
7.7 Applications of 7D/3D Modeling in Preliminary Design
7.6 Model Validation and Verification
7.7 Case Studies of 7D/3D Modeling in Naval Design
7.8 Introduction to Co-simulation in Naval Docking
2.7 Integration of 7D and 3D Models in Co-simulations
2.2 Advanced Co-simulation Techniques in Naval Docking
2.3 Data Exchange and Communication Between Simulators
2.4 Simulation of Different Ship Systems and Components
2.7 Analysis of Results and Optimization of Designs Using Co-simulation
2.6 Applications of co-simulation in performance evaluation.
2.7 Optimization of naval propulsion systems.
2.8 Case studies of co-simulation in naval design.
3.7 Fundamentals of naval rotor design.
3.2 Propeller and rotor theory.
3.3 Rotor modeling using different software.
3.4 Rotor performance analysis: thrust, torque, and efficiency.
3.7 Selection and design of optimized rotors.
3.6 Effects of cavitation and other phenomena on rotors.
3.7 Rotor design optimization techniques.
3.8 Practical cases of rotor modeling and design.
4.7 Application of 7D/3D modeling in coupling analysis.
4.2 Simulation of the ship-propellant-rudder interaction. 4.3 Vessel Maneuverability and Stability Analysis
4.4 Co-simulation for Propulsion Efficiency Optimization
4.7 Optimization Tools and Algorithms
4.6 Sensitivity Analysis and Key Parameter Study
4.7 Hull and Propulsion Design Improvement
4.8 Applications in the Design of New Vessels and Modernization of Existing Vessels
7.7 Simulation Methods for Evaluating Rotor Performance
7.2 Key Variables in Performance Evaluation: Thrust, Torque, Efficiency
7.3 Effect of Vessel Speed ​​and Load on the Rotor
7.4 Analysis of Rotor Energy Efficiency
7.7 Modeling Rotor Behavior Under Different Operating Conditions
7.6 Rotor Performance Optimization Techniques
7.7 Cavitation Simulation and Its Effects on Performance
7.8 Case Studies of Rotor Performance Optimization
6.7 Rotor Design for Different Types of Vessels
6.2 Rotor Modeling Using Specialized Software
6.3 Flow Simulation Around the Rotor
6.4 Rotor Performance Analysis Under Different Operating Conditions
6.7 Rotor Design Optimization for Efficiency and Noise Reduction
6.6 Rotor-Hull Interaction Simulation
6.7 Considerations Regarding Cavitation and Erosion
6.8 Practical Applications and Case Studies
7.7 Naval Design Optimization Methodologies
7.2 Use of Rotor Models and Simulations in the Design Process
7.3 Propulsion Efficiency Optimization
7.4 Noise and Vibration Reduction
7.7 Low-Noise Rotor Design
7.6 Integration of Multiple Objectives in Design
7.7 Naval Design Optimization Case Studies 7.8 Software Applications and Tools
8.7 Types of Simulations in Rotor Design
8.2 Modeling the Flow Around the Rotor
8.3 Performance Analysis: Thrust, Torque, Efficiency
8.4 Rotor Design Optimization
8.7 Design to Reduce Cavitation and Erosion
8.6 Integrating the Rotor into the Overall Vessel Design
8.7 Sensitivity Analysis and Key Parameter Study
8.8 Case Studies of Rotor Simulation and Design
8.8 Fundamentals of Naval Modeling: Key Principles and Concepts
8.8 Introduction to Naval Modeling Tools and Software
8.3 Types of Models: 8D, 8D and 3D in the Naval Context
8.4 Applications of Modeling in Naval Design and Analysis
8.5 Introduction to Simulation and Its Importance in Naval Design
8.8 8D Modeling of Naval Systems: Methodologies and Applications
8.8 3D Modeling of Naval Components: Techniques and Tools
8.3 Co-Simulation: Integration of 8D and 3D Models in Naval Analysis
8.4 Naval Docking: Implementation and Interaction Analysis
8.5 Case Studies: Application of 8D/3D Docking to Specific Naval Problems
3.8 Principles of Rotor Modeling: Geometry and Aerodynamics 3.8 Specialized Rotor Modeling Software: Application and Configuration
3.3 Rotor Performance Analysis: Thrust, Torque, and Efficiency
3.4 Rotor Modeling for Different Vessel Types: Propellers, Drives, and Steerable Rotors
3.5 Rotor Simulation: Flow and Performance Analysis under Operating Conditions
4.8 Optimization of Naval Couplings: Objectives and Methodologies
4.8 Sensitivity Analysis and Parametric Optimization in 8D/3D Models
4.3 Co-simulation Techniques for Coupling Optimization
4.4 Performance and Efficiency Evaluation in Optimized Couplings
4.5 Case Studies: Application of Optimization in Naval Designs
5.8 Rotor Performance Analysis: Methodologies and Key Parameters
5.8 Flow Simulation Around Rotors: CFD Techniques and Applications 5.3 Energy Efficiency Assessment of Rotors
5.4 Design and Analysis of Rotors for Different Operating Conditions
5.5 Case Studies: Rotor Performance Optimization in Naval Scenarios
6.8 Rotor Modeling: Software and Tool Selection
6.8 Rotor Simulation: Simulation Setup and Execution
6.3 Rotor Design: Geometry and Parameter Optimization
6.4 Results Analysis: Performance Interpretation and Evaluation
6.5 Integration of Rotor Design and Simulation into the Naval Design Process
7.8 Naval Design Optimization: Objectives and Strategies
7.8 Design of Experiments and Sensitivity Analysis in Naval Design
7.3 Rotor Performance Optimization: Application of Algorithms and Techniques
7.4 Integration of Rotor Models into the Design Process
7.5 Case Studies: Application of Optimization in Naval Projects
8.8 Rotor Simulation: Software and Tools
8.8 Rotor Design: Methods and Considerations
8.3 Naval Design Optimization: Methodologies and Techniques
8.4 Results Analysis: Performance and Efficiency Evaluation
8.5 Case Studies: Applications in Naval Design
9. 9D/3D Modeling: Fundamentals and Applications in Naval Design
9. Introduction to Co-Sims Orchestration for Naval Docking
3. Integration of 9D/3D Models in Naval Systems Simulations
4. Tools and Software for Naval Modeling and Simulation
5. Case Studies: Application of Co-Sims in Vessel Design
6. Optimization of Naval Designs Using 9D/3D Modeling
7. Results Analysis and Simulation Validation
8. Challenges and Trends in Naval Modeling and Simulation
9. Scenario Design and Sensitivity Analysis in Co-Sims
90. Project Presentations and Evaluations
9. Advanced 9D/3D Modeling Techniques for Complex Naval Systems 3.9. Configuration and Management of Advanced Co-Simulations.
4.3. Systems Coupling: Propulsion, Steering, and Stability.
5.4. Simulation of Operational Scenarios and Environmental Conditions.
6.5. Optimization of Energy Efficiency in Naval Couplings.
7.6. Computational Fluid Dynamics (CFD) Analysis in Co-Simulation.
8.7. Use of Experimental Data for Model Validation.
9.8. Implementation of Co-Simulation in the Design Process.
90.9. Risk Analysis and Mitigation in Advanced Simulations.
99.90. Practical Projects: Simulations of Real-World Cases.
3.9. Fundamentals of Rotor Design for Vessels.
4.9. Rotor Modeling: Theory and Numerical Methods. 5.3. Selection of airfoil profiles and blade design.
6.4. Simulation of rotor performance: thrust, torque, and efficiency.
7.5. Modeling of cavitation and its impact on design.
8.6. Analysis of rotor-hull interaction.
9.7. Tools and software specialized in rotor modeling.
90.8. Optimization of rotor design for different naval applications.
99.9. Case studies: rotor design for specific vessels.
99.90. Presentation of designs and evaluation of projects.
4.9. Analysis of naval propulsion systems using 9D/3D modeling.
5.9. Co-simulation for coupling analysis: propulsion-rudder-hull.
6.3. Evaluation of the performance of different propeller configurations. 7. 4. Optimization of coupling design to reduce resistance.
8. 5. Analysis of maneuverability and directional stability.
9. 6. Simulation of energy efficiency and fuel consumption.
90. 7. Optimization tools and genetic algorithms.
99. 8. Case studies: Optimization of couplings in different types of vessels.
99. 9. Sensitivity analysis and risk assessment.
93. 90. Final report and presentation of results.
5. 9. Key rotor performance parameters: thrust, torque, efficiency.
6. 9. Simulation of performance under different operating conditions.
7. 3. Influence of cavitation on rotor performance.
8. 4. Analysis of rotor-waterflow interaction.
9. 5. Simulation of performance in different hull designs. 90. 6. Performance optimization for different naval applications.
99. 7. Tools and software for performance simulation.
99. 8. Case studies: analysis of the performance of specific rotors.
93. 9. Evaluation of the influence of design on efficiency.
94. 90. Presentation of results and conclusions.
6. 9. Fundamentals of rotor modeling for naval design optimization.
7. 9. Modeling methods: finite elements, panel methods, CFD.
8. 3. Simulation of flow around the rotor: CFD and panel methods.
9. 4. Analysis of cavitation and its impact on design.
90. 5. Modeling of rotor-hull interaction: influence of the hull.
99. 6. Optimization of rotor design: algorithms and criteria.
99. 7. Software tools for modeling and simulation. 93. 8. Case studies: Application to different types of vessels.
94. 9. Presentation of optimized designs and results.
95. 90. Conclusions and future challenges.
7. 9. Principles of naval design optimization.
8. 9. Integration of rotor modeling into the optimization process.
9. 3. Definition of design objectives and constraints.
90. 4. Selection of optimization algorithms and parameters.
99. 5. Optimization of rotor design for different applications.
99. 6. Sensitivity analysis and tradeoff studies.
93. 7. Tools and software for design optimization.
94. 8. Case studies: optimization of ship design.
95. 9. Validation of results and uncertainty analysis.
96. 90. Presentation and discussion of final projects.
8. 9. Introduction to Naval Rotor Modeling and Simulation
9. 9. Tools and Software for Rotor Simulation
90. 3. Simulation of Rotor Performance Under Different Conditions
99. 4. Optimization of Rotor Design for Efficiency and Performance
99. 5. Analysis of Cavitation and Its Impact on Design
93. 6. Integration into the Naval Design Process
94. 7. Case Studies: Application to Different Types of Vessels
95. 8. Analysis of the Influence of Design on Energy Efficiency
96. 9. Risk Assessment and Model Validation
97. 90. Presentation of Final Projects and Results
9. 9. Rotor Modeling: Concepts and Methods
90. 9. Simulation of Rotor Performance: Tools and Techniques 99. 3. Rotor Design: Optimization and Analysis
99. 4. Rotor Integration in Naval Design
93. 5. Rotor-Hull Interaction Analysis
94. 6. Cavitation Simulation
95. 7. Energy Efficiency Optimization
96. 8. Case Studies: Applications in Different Types of Vessels
97. 9. Project and Results Presentation
98. 90. Future Trends and Challenges in Naval Design with Rotors
1. Mastery of 1D/3D Modeling and Co-Sim Orchestration for Naval Docks
2. Advanced Modeling and Co-Simulation of 1D/3D Naval Docks
3. Expert Mastery of Rotor Modeling for Naval Design: Performance and Simulation
4. Analysis and Optimization of Naval Docks Using 1D/3D Modeling and Co-Simulation
5. Rotor Modeling: Performance Optimization in Naval Simulations
6. Rotor Modeling and Simulation for Naval Design Optimization
7. Naval Design Optimization Using Rotor Modeling and Simulation
8. Rotor Modeling: Simulation and Optimization in Naval Design
9. Conceptual Design: Architecture Selection and Initial Parameters
10. Design Evaluation: Hydrodynamics and Stability
- Hands-on methodology: test-before-you-trust, design reviews, failure analysis, compliance evidence.
- Software (depending on licenses/partners): MATLAB/Simulink, Python (NumPy/SciPy), OpenVSP, SU2/OpenFOAM, Nastran/Abaqus, AMESim/Modelica, acoustics tools, planning toolchains DO-178C.
- SEIUM Laboratories: scale rotor bench, vibrations/acoustics, EMC/Lightning pre-compliance, HIL/SIL for AFCS, data acquisition with strain gauging.
- Standards and compliance: EN 9100, 17025, ISO 27001, GDPR.
Proyectos tipo capstones
Admisiones, tasas y becas
- Profile: Background in Computer Engineering, Mathematics, Statistics, or related fields; practical experience in NLP and valued information retrieval systems.
- Documentation: Updated CV, academic transcript, SOP/statement of purpose, project examples or code (optional).
- Process: Application → Technical evaluation of profile and experience → Technical interview → Review of case studies → Final decision → Enrollment.
- Fees:
- Single payment: 10% discount.
- Payment in 3 installments: No fees; 30% upon registration + 2 equal monthly payments of the remaining 35%.
Monthly payment: available with a 7% commission on the total; annual review.
Scholarships: based on academic merit, financial need, and promoting inclusion; agreements with companies in the sector for partial or full scholarships.
See “Calendar & Calls for Applications,” “Scholarships & Grants,” and “Fees & Financing” in the SEIUM mega-menu.
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