Diploma in 3D Visualization for Engineering and Cabin Testing
Sobre nuestro Diploma in 3D Visualization for Engineering and Cabin Testing
The Diploma in 3D Visualization for Engineering and Cabin Testing focuses on the application of cutting-edge technologies for creating detailed three-dimensional models and their use in the design, simulation, and evaluation of cabins and components in engineering environments. Advanced tools for 3D modeling, photorealistic rendering, and data integration from diverse sources are explored for the creation of virtual prototypes. The program includes the implementation of virtual simulations and cabin testing, with special emphasis on ergonomics, user experience, and data visualization to optimize the functionality and design of interior spaces. The diploma program provides hands-on experience using CAD, interactive visualization, and virtual reality (VR) software, integrating lighting modeling and component animation for design presentation and analysis. Participants develop skills in 3D visualization project management, from conceptualization to implementation, encompassing feasibility studies and the preparation of technical reports to support design and production decisions. The training is geared towards the requirements of the automotive, aeronautical, and architectural industries. Target keywords (naturally occurring in the text): 3D visualization, cockpit testing, 3D modeling, rendering, virtual simulation, ergonomics, virtual reality, interior design, engineering, virtual prototyping, diploma program.
Diploma in 3D Visualization for Engineering and Cabin Testing
- 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
1.390 $
Competencias y resultados
Qué aprenderás
1. Mastery of 3D Visualization: Engineering, Cabin Testing, and Project Optimization [The following appears to be unrelated and possibly machine-translated gibberish:] ...
- 3D modeling and simulation of complex naval structures, including hulls, decks, and superstructures.
- Analysis of the stability and buoyancy of vessels under various loading and sea conditions.
- Proficiency in specialized naval design software, such as CAD/CAM/CAE.
- Optimization of hull shape to reduce drag and improve energy efficiency.
- Design of propulsion systems, including propellers, rudders, and steering systems.
- Evaluation of the structural strength of naval components using finite element analysis (FEA).
- Application of shipbuilding codes and standards, such as the Society of Shipbuilding Classification Rules.
- Management of shipbuilding and repair projects, including planning, cost control, and supervision.
- Knowledge of naval materials, including steels, aluminum, and composites.
and its properties.
Risk and safety analysis in the design and operation of ships.
2. Advanced 3D Visualization for Cabin Engineering and Simulation
2. Advanced 3D Visualization for Engineering and Cabin Simulation:
- 3D Modeling and Simulation of Complex Aeronautical Systems: Learn to create detailed and accurate models of aeronautical components and systems, using cutting-edge software to simulate their behavior under various conditions.
- Structural and Aerodynamic Analysis: Delve into finite element analysis (FEA) to evaluate the structural strength of cabins and components, as well as aerodynamic flow simulation to optimize design and reduce drag.
- Systems Integration and Cabin Simulation: Master the techniques for integrating onboard systems into 3D models, including electrical, flight control, and avionics systems.
Learn to simulate cockpit operation in real time, enabling the evaluation of human-machine interaction and the optimization of ergonomics.
Advanced Visualization and Virtual Reality: Explore the use of advanced visualization techniques, including virtual reality (VR) and augmented reality (AR), for immersive cockpit design and simulation. Learn to use these tools for design validation, pilot training, and optimizing the user experience.
Design and Manufacturing Process Optimization: Apply the acquired knowledge to optimize cockpit design, considering factors such as safety, efficiency, ergonomics, and aesthetics. Learn to use simulation tools to evaluate different design options and select the most suitable solution.
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. 3D Visualization Domain: Engineering, Testing Booth, and Performance Analysis
- Develop accurate 3D models of naval components and complete vessels.
- Use specialized software for the simulation and visualization of naval designs.
- Apply reverse engineering techniques to create 3D models from existing data.
- Design and analyze the structure of the test cabin, considering factors such as ergonomics and safety.
- Optimize the cabin design to facilitate data analysis and performance evaluation.
- Integrate instrumentation and control systems in the test cabin.
- Evaluate the performance of vessels and naval systems using 3D simulations.
- Analyze the hydrodynamics, aerodynamics, and stability of naval designs.
- Identify areas for design improvement to optimize performance and Efficiency.
5. 3D Rotor Modeling: Engineering, Testing, and Performance Analysis
- Fundamentals of 3D Rotor Modeling: You will understand the essential principles of 3D modeling applied to rotors, including software selection and modeling techniques specific to rotating aircraft components.
- Rotor Engineering: Design and Structural Analysis: You will learn to apply engineering principles to the structural design and analysis of rotors, including material selection, shape optimization, and stress and strain analysis using finite element analysis (FEA) software.
- Rotor Dynamics Analysis: You will study the dynamic phenomena that affect rotors, such as vibration, flutter, and resonance, and learn to model and simulate these phenomena to predict and mitigate problems.
- Test Chamber Modeling: You will become familiar with the design and simulation of test chambers for rotors, including sensor configuration, data acquisition, and results analysis.
- Rotor Performance Analysis: You will master techniques for analyzing rotor performance, including determining efficiency, load capacity, and flight characteristics, using 3D models and simulation software.
- Composite and Laminated Materials: You will explore the use of composite materials in rotor manufacturing, including laminate design and analysis, material selection, and failure analysis.
- Advanced Modeling Techniques: You will acquire advanced skills in 3D modeling, including creating complex meshes, simulating nonlinear phenomena, and topological optimization.
- Software and Tool Integration: You will learn to integrate different software and tools for rotor modeling, analysis, and simulation, including software CAD/CAM, FEA, and CFD.
- Practical Applications and Case Studies: You will participate in practical projects and case studies that will allow you to apply the knowledge acquired to real-world problems in rotor engineering.
- Design and Analysis of Critical Components: You will focus on the design and analysis of critical rotor components, such as blades, hubs, and control systems, to ensure safety and optimal performance.
6. Rotor Modeling and Performance: Engineering and 3D Cabin Testing
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 3D Visualization for Engineering and Cabin Testing
- Engineers with degrees in Naval Engineering, Marine Engineering, Mechanical Engineering, or related naval disciplines.
- Professionals in the naval industry, including shipyards, naval design firms, and marine equipment and service providers.
- Technical and operational personnel from navies, coast guards, and other naval organizations.
- Naval engineers who wish to specialize in 3D visualization and cabin simulation for the design, analysis, and testing of vessels.
- 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 — Introduction to 3D Naval and Cabin Modeling
1.1 Fundamentals of 3D Modeling in Naval Engineering
1.2 Introduction to Cabin Simulation
1.3 3D Modeling Software and Tools for Naval Design
1.4 Principles of Parametric Design in 3D Modeling
1.5 Representation of Surfaces and Curves in 3D Modeling
1.6 Importance of 3D Visualization in Naval Engineering
1.7 Introduction to Ship Structure and Design
1.8 Principles of Hydrodynamics and Buoyancy
1.9 Applications of 3D Modeling in Structural Analysis
1.10 Introduction to the Virtual Test Cabin
1.10
2.2 Introduction to Naval 3D Modeling Tools
2.2 Basic 3D Modeling Concepts: Solids, Surfaces, and Meshes
2.3 User Interface and Navigation in Modeling Software
2.4 Modeling Basic Shapes: Cubes, Cylinders, Spheres
2.5 Creating and Editing 3D Objects: Extrusion, Revolve, Boolean Operations
2.6 Importing and Exporting 3D File Formats
2.7 Applications of 3D Modeling in the Naval Industry
2.8 Resources and Tutorials for Learning 3D Modeling
2.9 Design Principles for Naval 3D Visualization
2.20 Practical Exercises in Modeling Basic Naval Components
2.2 3D Cabin Interior Design: Ergonomics and Functionality
2.2 3D Simulation of Navigation and Environmental Conditions
2.3 Lighting and Texturing for a Realistic Visual Experience
2.4 Integrating Instruments and Control Systems in the Simulation
2.5 Analyzing Visibility and Field of View in the Cockpit
2.6 Animation of movements and special effects in the simulation
2.7 Usability and user experience testing in the virtual cockpit
2.8 Optimizing simulation performance and fluidity
2.9 Tools and techniques for creating simulation scenarios
2.20 Examples of cockpit simulation applications in the naval industry
3.2 3D modeling of ship hulls: shapes and structures
3.2 3D modeling of propulsion systems: propellers, rudders, and engines
3.3 3D modeling of navigation and communication systems
3.4 Integration of components and systems into the overall 3D model
3.5 Structural and strength analysis of naval components
3.6 Computational fluid dynamics (CFD) simulation in 3D models
3.7 Design optimization for energy efficiency and cost reduction
3.8 Creating drawings and technical documentation from the 3D model
3.9 Collaboration and teamwork in naval 3D modeling projects
3.20 Case studies 3D Modeling in Naval Engineering Projects
4.2 Identifying the Objectives and Scope of the 3D Project
4.2 Selecting 3D Modeling Software and Tools
4.3 Planning the Project Workflow and Schedule
4.4 Optimizing the Geometry and Topology of 3D Models
4.5 Simplifying and Reducing the Complexity of Models
4.6 Using Texturing and UV Mapping Techniques to Optimize Performance
4.7 Optimizing Lighting and Real-Time Rendering
4.8 Managing and Organizing Project Files and Resources
4.9 Version Control and Collaboration in 3D Projects
4.20 Evaluating and Analyzing 3D Project Results
5.2 Introduction to Performance Analysis in 3D Models
5.2 Simulating Fluid Flow Around Hulls and Propellers
5.3 Analyzing Drag and Propulsion Efficiency
5.4 Simulating Wind and Wave Conditions in 3D Models
5.5 Stability Analysis and the behavior of the models at sea
5.6 Visualization and analysis of 3D performance data
5.7 Design optimization to improve performance and efficiency
5.8 Use of data analysis tools for decision-making
5.9 Validation and verification of analysis results
5.20 Practical cases of performance analysis in naval projects
6.2 Introduction to propeller and rotor theory
6.2 3D modeling of propeller airfoils
6.3 Design and modeling of propellers of different types and configurations
6.4 Simulation of fluid flow around propellers in 3D models
6.5 Analysis of propeller efficiency and performance
6.6 Optimization of propeller design for different applications
6.7 Use of specialized software for propeller modeling and analysis
6.8 Integration of propellers into 3D models of propulsion systems
6.9 Validation of propeller models through testing and experimentation
6.20 Applications of 3D modeling of Propellers in the Naval Industry
7.2 Preparing the 3D Model for Cabin Evaluation
7.2 Integrating Instruments and Control Systems in the Simulation
7.3 Simulating Navigation and Environmental Conditions in the Cabin
7.4 Evaluating Visibility and Field of View in the Cabin
7.5 Analyzing Model Behavior and Maneuverability
7.6 Usability and User Experience Testing in the Virtual Cabin
7.7 Collecting and Analyzing Real-Time Performance Data
7.8 Optimizing the Design Based on Evaluation Results
7.9 Reporting and Presenting Cabin Evaluation Results
7.20 Practical Case Studies of Cabin Evaluation of 3D Rotor Models
8.2 Preparing the 3D Model for Cabin Test Validation
8.2 Designing the Experimental Configuration for the Cabin Test
8.3 Collecting Performance Data During Testing
8.4 Comparative Analysis of 3D Model and Test Results
8.5 Identifying Discrepancies and Areas for Improvement The model
8.6 Adjustments and modifications to the 3D model based on the results
8.7 Validation of the 3D model by comparison with real data
8.8 Documentation and reporting of the validation results
8.9 Implementation of improvements in the rotor design
8.20 Validation case studies in cabin testing of 3D models
8.6 Adjustments and modifications to the 3D model based on the results
8.7 Validation of the 3D model by comparing it with real data
8.8 Documentation and reporting of the validation results
8.9 Implementation of improvements in the rotor design
8.20 Validation case studies in cabin testing
3.3 Introduction to 3D Modeling in Naval Engineering
3.2 Fundamentals of 3D Modeling Software (CAD)
3.3 Modeling of Hulls and Naval Structures
3.4 Design of Propulsion Systems and Propellers
3.5 Modeling of Internal Equipment and Components
3.6 3D Visualization and Presentation Techniques
3.7 Simulation of Basic Navigation Scenarios
3.8 Buoyancy and Stability Analysis
3.9 Design Optimization Using 3D Modeling
3.30 Integration of 3D Modeling into the Naval Design Process
3.30
4.4 Introduction to Naval Engineering and 3D Visualization: Fundamental Principles
4.2 Hull Design: 3D Modeling and Hydrodynamic Simulation
4.3 Propeller Design: 3D Modeling and Performance Analysis
4.4 Onboard Systems: 3D Modeling and Systems Simulation
4.5 Virtual Test Chamber: Environment Creation and Configuration
4.6 Computational Flow Analysis (CFD) in Naval Practice
4.7 Validation of 3D Models: Comparison with Real Data and Optimization
4.8 Design of Yachts and Recreational Craft: Specific Applications
4.9 Optimization of Naval Projects: Strategies and Tools
4.40 Case Studies: Real-World Applications and Industry Challenges
5.5 Introduction to Naval Propulsion and Rotor Types
5.5 Principles of Aerodynamics and Hydrodynamics Applied to Rotors
5.3 Materials and Shipbuilding for Rotors
5.4 International and National Regulations Applicable to Rotors
5.5 Design and Safety Standards in Propulsion Systems
5.6 Regulations on Emissions and Energy Efficiency in Ships
5.7 Ship Classification and Rotor Design Requirements
5.8 Technical Documentation and Naval Design Drawings
5.9 Certifications and Approvals of Rotors and Systems
5.50 Case Study: Analysis of Regulations in Rotor Design
5.50
6.6 Introduction to 3D Rotor Modeling: Types and Applications in Naval Engineering
6.2 Fundamental Principles of 3D Modeling: Essential Software and Tools
6.3 Rotor Design: Key Parameters and Engineering Considerations
6.4 3D Rotor Modeling: Techniques and Best Practices
6.5 Integrating the 3D Model into Cabin Simulation: Configurations and Scenarios
6.6 Rotor Performance Analysis in Cabin: Data Evaluation and Results
6.7 Rotor Design Optimization: Iterations and Simulation-Based Improvements
6.8 3D Model Validation: Correlation with Experimental Data and Cabin Testing
6.9 Case Studies: Practical Examples of Rotor Modeling and Simulation
6.60 Conclusions and Future Trends in 3D Rotor and Cabin Modeling
7.7 Introduction to Naval Propulsion and its Components
7.2 Operating Principles of Naval Rotors
7.3 Types of Rotors and their Applications
7.4 Materials and Technologies in Rotor Manufacturing
7.7 Introduction to Hydrodynamics and Aerodynamics in Rotor Design
7.6 International and National Regulations Applicable to Naval Design and Construction
7.7 Codes and Standards of the Society of Naval Engineers and Marine Architects (SNAME)
7.8 Introduction to Classification Rules of Societies such as ABS, DNV, Lloyd’s Register
7.9 Examples of Regulation Application in Rotor Design
7.70 Future of Naval Propulsion and Rotors
8.8 Principles of 3D Modeling for Naval Simulation
8.8 Integration of CAD Data and Parametric Design
8.3 Advanced Texturing and Rendering Techniques
8.4 Workflow Optimization for Cockpit Analysis
8.5 Creating Realistic Test Environments
8.6 3D User Interaction Simulation
8.7 Performance Analysis and Design Evaluation
8.8 Validation of 3D Models through Cockpit Testing
8.8 Report Generation and Documentation
8.80 Integration with Naval Simulation Software
8.80
9.9 Introduction to 3D Modeling for Naval Engineering: Concepts and Software
9.9 3D Model Design: Construction of Hulls and Naval Structures
9.3 Systems Modeling: Machinery, Piping, and Onboard Equipment
9.4 Cabin Simulation: Virtual Environment for Testing and Validation
9.5 Performance Analysis: Calculating Stability and Resistance
9.6 Design Optimization: Iteration and Continuous Improvement
9.7 Rotor Modeling: Propellers and Propulsion Systems
9.8 Integration of 3D Models: Assembly and Project Presentation
9.9 Case Studies: Practical Examples and Real-World Applications
9.90 Trends and Future: Evolution of 3D Visualization in the Naval Industry
1.1 Principles of 3D Modeling for Naval Engineering
1.2 3D Design Software and Tools
1.3 Modeling of Hulls and Naval Structures
1.4 Simulation of Flows and Hydrodynamic Resistance
1.5 Design and Simulation of Test Chambers
1.6 Optimizing Designs for Performance and Efficiency
1.7 Data Analysis and Key Metrics
1.8 Naval Design Regulations and Standards
1.9 Integrating 3D Modeling into the Design Process
1.10 Final Project: Evaluation and Presentation of a Naval Design
1.10
- 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.
¿Tienes dudas?
Nuestro equipo está listo para ayudarte. Contáctanos y te responderemos lo antes posible.