Diploma in Aeroelasticity and Comfort of Footbridges and Bridges
Sobre nuestro Diploma in Aeroelasticity and Comfort of Footbridges and Bridges
The Diploma in Aeroelasticity and Comfort of Footbridges and Bridges focuses on the study of the dynamic interaction between the structure of bridges and footbridges and aerodynamic and environmental forces. It addresses the analysis of phenomena such as flutter, wind-induced vibrations, and structural dynamic behavior, applying techniques of advanced structural analysis, numerical simulation, and finite element modeling (FEM). It focuses on the design of strong and comfortable structures, considering aspects such as modal response, structural fatigue, and user comfort, using structural dynamics and computational aerodynamics (CFD) tools. The program provides practical knowledge in the evaluation of aeroelastic stability, vibration mitigation, and design for pedestrian comfort and compliance with current regulations. It includes the study of sensors and monitoring systems for evaluating dynamic behavior in service. This training prepares professionals as structural engineers, structural dynamics analysts, and bridge and footbridge designers, enabling them to address the challenges of modern civil engineering.
Target keywords (naturally occurring in the text): aeroelasticity, comfort, bridges, footbridges, structural analysis, vibrations, flutter, structural dynamics, FEM, structural design.
Diploma in Aeroelasticity and Comfort of Footbridges and Bridges
- Modalidad: Online
- Duración: 8 meses
- Horas: 900 H
- Idioma: ES / EN
- Créditos: 60 ECTS
- Fecha de matrÃcula: 30-04-2026
- Fecha de inicio: 10-06-2026
- Plazas disponibles: 13
1.199 $
Competencias y resultados
Qué aprenderás
1. Aeroelastic Analysis and Optimal Design of Bridges and Footbridges
- Analysis of the aeroelastic response of bridges and footbridges, including phenomena such as flutter.
- Application of structural optimization techniques to achieve efficient and safe designs.
- Study of fluid-structure interaction and its influence on stability and dynamic behavior.
2. Aeroelastic Evaluation, Structural Dynamics, and Comfort in the Design of Bridges and Footbridges
- Understand the fundamentals of aeroelasticity in bridges and footbridges, including the interaction between aerodynamic forces, structural elasticity, and dynamics.
- Identify and evaluate critical aeroelastic phenomena, such as flutter and instability, and analyze their impact on the safety and performance of structures.
- Apply modeling and simulation techniques to predict the aeroelastic behavior of bridges and footbridges, using specialized software.
2.
- Analyze the structural dynamics of bridges and footbridges, including the response to static and dynamic loads, such as wind, traffic, and vibrations.
- Evaluate the response of structures to resonance phenomena and cyclic loading conditions, and understand fatigue mechanisms.
- Develop finite element (FE) models to simulate structural dynamics and analyze the distribution of stresses and strains.
3.
- Evaluate comfort in bridges and walkways, considering the effects of vibrations and movement on users and the stability of the structure.
- Understand the norms and standards related to comfort and safety in bridges and walkways, and the methodologies for measuring and controlling them.
- Apply design techniques to improve comfort and minimize vibrations, including the use of dampers and active control systems.
4.
- Study the application of composite materials, with emphasis on their use in bridges and walkways, and design structures that are lightweight and strong.
- Analyze the joining and assembly techniques of structural components, including adhesive methods and mechanical systems, to ensure structural integrity.
- Use finite element analysis (FEA) tools to evaluate the behavior of composite laminates, joints, and bonded joints.
6. Implement damage tolerance strategies to assess the safety of structures in the presence of defects or damage.
Apply non-destructive testing (NDT) techniques, such as ultrasonic testing (UT), radiography (RT), and thermography, for the inspection and evaluation of bridges and footbridges.
Develop condition-based inspection and maintenance plans, and strategies to mitigate the impact of damage on safety and performance.
5.
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. Comprehensive Aeroelastic Study and Design Comfort in Bridges and Footbridges
4. Comprehensive Aeroelastic Study and Design Comfort in Bridges and Footbridges
- Evaluate the complete aeroelastic response of structures, including the analysis of key phenomena such as flap-lag-torsion coupling, whirl flutter instability, and the effects of structural fatigue.
- Design and dimension structural components of bridges and footbridges using composite materials, paying special attention to joints and bonded joints, and using finite element analysis (FEA) tools.
- Apply damage tolerance methodologies to evaluate resistance to failure and damage propagation, and employ non-destructive testing (NDT) techniques, such as ultrasonic testing (UT), radiography (RT), and thermography, for inspection and quality control of the structures.
5. Aeroelastic Engineering: Analysis and Optimization of Comfort in Footbridges and Bridges
5. Aeroelastic Engineering: Analysis and Optimization of Comfort in Footbridges and Bridges
- Evaluate the aeroelastic response of structures, including the analysis of phenomena such as the Von Kármán vortex and galloping.
- Master the use of CFD (Computational Fluid Dynamics) simulation software to predict aerodynamic loads on bridges and footbridges.
- Apply modal modeling and frequency analysis techniques to identify critical vibration modes.
- Understand and mitigate the effects of flutter and divergence in suspension and cable-stayed bridges.
- Design dampers and vibration control systems to improve comfort and structural safety.
- Analyze the influence of wind on the design of pedestrian walkways, considering resonance effects.
- Conduct sensitivity studies to evaluate the robustness of the design against variations in wind conditions.
- Apply the principles of structural optimization to reduce the weight and cost of structures.
- Learn to interpret and apply the relevant design standards and codes for bridges and walkways.
6. Aeroelastic Research and Comfort: Design and Evaluation of Bridges and Footbridges
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 Aeroelasticity and Comfort of Footbridges and Bridges
- 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 — Aeroelastic Fundamentals and Initial Design**
1.1 Introduction to Aeroelasticity in Bridges and Footbridges: Key Concepts
1.2 Principles of Initial Design: Aeroelastic Considerations
1.3 Aeroelastic Loads: Identification and Evaluation
1.4 Simplified Structural Modeling for Preliminary Analysis
1.5 Basic Aeroelastic Stability Analysis
1.6 Introduction to Comfort: Definition and Influencing Factors
1.7 Deck Design: Influence on Aeroelastic Behavior
1.8 Material Selection: Aeroelastic and Economic Impact
1.9 Initial Approaches to Optimal Design
1.10 Case Studies: Examples of Design and Initial Analysis
1.10
2.2 Introduction to Aeroelasticity: Fundamental concepts and their application in bridges and footbridges.
2.2 Principles of Structural Dynamics: Vibration analysis and oscillation modes.
2.3 Aeroelastic Evaluation Methods: Static and dynamic analysis.
2.4 Wind Modeling: Definition of aerodynamic loads and wind models.
2.5 Evaluation of Aeroelastic Response: Analysis of stability and wind-induced vibrations.
2.6 Design for Comfort: Criteria and strategies for minimizing vibrations.
2.7 Wind-Structure Interaction Analysis: Computational Fluid Dynamics (CFD) models.
2.8 Case Studies: Analysis of real-world examples of bridges and footbridges.
2.9 Regulations and Standards: Regulatory considerations in aeroelastic design.
2.20 Conclusions and Future Directions: Trends in aeroelastic research and design.
3.3 Fundamentals of Aeroelasticity in Bridges and Footbridges
3.2 Aerodynamic Load Modeling
3.3 Modal Analysis and Dynamic Response
3.4 Introduction to Human Comfort in Structures
3.5 Advanced Analysis Methods: CFD and FEM
3.6 Wind Assessment and its Impact on Design
3.7 Design to Mitigate Wind-Induced Vibrations
3.8 Design Optimization for Comfort
3.9 Case Studies: Design of Existing Bridges and Footbridges
3.30 International Standards and Regulations
4.4 Fundamental Principles of Aeroelasticity in Bridges
4.2 Aerodynamic Loads and Their Influence on Structural Design
4.3 Basic Aeroelastic Modeling and Simulation of Bridges
4.4 Evaluation of Comfort and Vibrations in Pedestrian and Vehicular Bridges
4.5 Preliminary Design and Material Selection Considering Aeroelasticity
4.6 Analysis of Aeroelastic Stability and the Buckling Phenomenon
4.7 Vibration Mitigation and Comfort Improvement Techniques
4.8 Case Studies: Practical Examples of Bridges and Footbridges
4.9 Aeroelastic Design Standards and Regulations for Bridges
4.40 Design Optimization to Reduce Aeroelastic Sensitivity
4.5
5.5 Fundamentals of Aeroelasticity: Fluid-Structure Interaction
5.5 ​​Key Concepts in Bridge Design: Aerodynamic and Dynamic Loads
5.3 Aeroelastic Phenomena: Flutter, Divergence, Wind-Induced Oscillations
5.4 Regulations and Standards for Bridge Design: Eurocode, AASHTO
5.5 Case Study: Failure Analysis and Lessons Learned
5.5 Aeroelastic Evaluation Methods: Modal Analysis, Response Spectrum
5.5 Structural Dynamics: Free and Forced Vibrations, Damping
5.3 Comfort Analysis: Vibration Criteria and Human Response
5.4 Structural Analysis Software: Introduction and Applications
5.5 Numerical Simulation: Finite Elements and CFD in Bridge Design
3.5 Advanced Wind Modeling: Wind Profiles, Turbulence, and Gusts
3.5 Flutter Analysis: Solution Methods and Stability
3.3 Comfort: Evaluation and Mitigation Criteria Vibrations
3.4 Parametric Analysis: Design Optimization and Sensitivity
3.5 Case Studies: Innovatively Designed Bridges and Footbridges
4.5 Comprehensive Aeroelastic Analysis: Complete Methodology
4.5 Comfort Assessment: Measurement and Analysis Techniques
4.3 Performance-Based Design: Optimization of Structural Response
4.4 Risk Assessment: Hazard Identification and Mitigation
4.5 Case Studies: Design and Analysis of Bridges and Footbridges
5.5 Aeroelastic Engineering Principles: Applications in Bridges and Footbridges
5.5 Design Optimization: Vibration Reduction and Comfort Improvement
5.3 Design of Damping Systems: Types and Applications
5.4 Sensitivity Analysis: Effect of Design Parameters
5.5 Design and Optimization: Case Studies of Bridges and Footbridges
6.5 Aeroelastic Research: Methodologies and Tools
6.5 Research-Based Design: Applications and Advances
6.3 Analysis of Experimental Data: Model Validation
6.4 Design of Bridges and Footbridges: Advanced Design and Analysis
6.5 Case Studies: Aeroelastic Research and Structural Design
7.5 Deep Aeroelasticity: Complex and Advanced Phenomena
7.5 Comfort: Evaluation and Improvement in Footbridges
7.3 Design of Aerial Structures: Methodologies and Analysis
7.4 Case Studies: Detailed Analysis of Bridges and Footbridges
7.5 Experimental Validation: Wind Tunnel and Field Testing
8.5 Aeroelastic Modeling: Tools and Techniques
8.5 Numerical Simulation: Simulation of Structural Behavior
8.3 Comfort Optimization: Strategies and Methodologies
8.4 Simulation and Optimization: Sensitivity Analysis
8.5 Case Studies: Modeling and Simulation of Bridges
8.5
6.6 Fundamental Concepts of Aeroelasticity
6.2 Importance of Aeroelasticity in Bridges and Footbridges
6.3 Factors Influencing Aeroelastic Behavior
6.4 Historical Failures and Lessons Learned
6.5 Applicable Legislation and Regulations
2.6 Modeling of Structures and Aerodynamic Loads
2.2 Numerical Simulation Methods (CFD, FEM)
2.3 Model Validation and Results Analysis
2.4 Aeroelastic Simulation Software
2.5 Data Interpretation and Report Generation
3.6 Definition and Evaluation of Comfort
3.2 Design Criteria for Comfort
3.3 Vibration Analysis and Structural Response
3.4 Vibration Mitigation Methods
3.5 Design of Damping and Control Systems
4.6 Integration of Aeroelastic, Structural, and Comfort Analysis
4.2 Case Studies of Landmark Bridges and Footbridges
4.3 Sensitivity Analysis and Design Optimization
4.4 Performance-Based Design
4.5 Service Life and Durability Assessment
5.6 Practical Application of Aeroelastic Engineering
5.2 Design of Wind-Resistant Bridges and Footbridges
5.3 Material Selection and Structural Configuration
5.4 Design of Construction Details
5.5 Safety and Maintenance Considerations
6.6 Practical Case Studies in Aeroelastic Design
6.2 Failure Analysis and Lessons Learned
6.3 Research into New Technologies and Methods
6.4 Development of Models and Analysis Tools
6.5 Presentation and Discussion of Research Results
7.6 Advanced Aeroelasticity Analysis of Footbridges
7.2 Effects of Wind-Structure Interaction
7.3 Aeroelastic Behavior under Extreme Conditions
7.4 Design of Long-Span Footbridges and Complex Shapes
7.5 Implementation of Aeroelastic Control Systems
8.6 Structural Optimization Techniques
8.2 Design Optimization for Comfort
8.3 Multi-Objective Optimization Methodology
8.4 Design of Lightweight and Efficient Structures
8.5 Evaluation of Costs and benefits
7.7 Fundamentals of Aeroelasticity in Bridge Design
7.2 Aerodynamic Loads and Structural Response
7.3 Aeroelastic Stability: Key Concepts
7.4 Preliminary Design and Material Selection
7.7 Modeling and Simulation: Introduction
7.6 Design Factors: Wind, Geometry, and Environment
7.7 Case Studies: Bridge Failures and Successes
7.8 Design Standards and Regulations
7.9 Analysis Tools: Software and Methods
7.70 Sustainable Design and Environmental Impact Considerations
2.7 Introduction to Aeroelastic Evaluation
2.2 Structural Dynamics Analysis
2.3 Vibration Modes and Natural Frequencies
2.4 Dynamic Behavior Under Wind Loads
2.7 Comfort Evaluation in Bridges and Footbridges
2.6 Modal Analysis and Time Response
2.7 Wind Tunnel Testing: Methodology and Results
2.8 Design for the Seismic Resilience
2.9 Simulation Software: Practical Applications
2.70 Case Studies: Risk Assessment and Mitigation
3.7 Introduction to Advanced Aeroelasticity Analysis
3.2 Fluid-Structure Interaction (FSI) Modeling
3.3 CFD Simulation Techniques for Overhead Structures
3.4 Comfort Assessment: Metrics and Criteria
3.7 Wind Influence on Design
3.6 Fatigue and Durability Analysis
3.7 Design for Vortex and Flutter Mitigation
3.8 Case Studies: Suspension and Cable-Stayed Bridges
3.9 Advanced Software Tools
3.70 Aeroelastic Design Optimization
4.7 Introduction to Comprehensive Aeroelastic Analysis
4.2 Integration of Analysis Methods
4.3 Sensitivity Analysis and Parametric Optimization
4.4 Environmental Impact and Sustainability in Design
4.7 Comfort Pedestrian and Cyclist
4.6 Risk Analysis and Mitigation Planning
4.7 Bridge Design and User Interaction
4.8 Case Studies: Comprehensive Bridge Design
4.9 Use of Specialized Software
4.70 Quality Control and Design Verification
7.7 Principles of Aeroelastic Engineering
7.2 Structural Design Optimization
7.3 Aerodynamic Design and its Optimization
7.4 Comfort Optimization: Analysis and Techniques
7.7 Design for Wind-Induced Vibration Reduction
7.6 Implementation of Dampers and Active Control Systems
7.7 Design Optimization: Methodology and Tools
7.8 Case Study: Optimal Design of Pedestrian Overpasses
7.9 Cost-Benefit Analysis
7.70 Design for Sustainability and Carbon Footprint Reduction
6.7 Introduction to Aeroelastic Research
6.2 Research Methodology
6.3 Design of Experiments
6.4 Data Analysis and Results
6.7 Design and Evaluation of New Bridge Models
6.6 Comfort Evaluation: Design and Methods
6.7 Validation of Numerical Models
6.8 Case Studies: Research on Existing Bridges
6.9 Publication and Dissemination of Results
6.70 Application of Research to Design
7.7 Introduction to Deep Aeroelasticity
7.2 Advanced Aeroelasticity Modeling
7.3 Fluid-Structure Interaction in Overpasses
7.4 Analysis of Nonlinear Behavior
7.7 Design for Mitigating Aeroelastic Problems
7.6 Comfort and Safety Evaluation in Overpasses
7.7 Design of the Overpass and its Environment
7.8 Case Studies: Overpasses with Aeroelastic Problems
7.9 Advances in Simulation Techniques
7.70 Sustainable Design for the Future
8.7 Introduction to Modeling Aeroelastic
8.2 Simulation Methods in Design
8.3 Structural Response Modeling
8.4 Comfort Optimization in Design
8.7 Design for Vibration Reduction
8.6 Wind Simulation and its Effects
8.7 Simulation Software and Tools
8.8 Case Studies: Simulation of Bridges and Footbridges
8.9 Risk Analysis and Mitigation
8.70 Design with a Focus on Sustainability and Comfort
8.7
8.8 Introduction to Aeroelastic Modeling
8.8 Fundamentals of Aeroelastic Simulation
8.3 Modeling of Bridges and Footbridges
8.4 Structural Analysis with Specialized Software
8.5 Aeroelastic Optimization Techniques
8.6 Comfort and Safety Simulation
8.7 Model Validation and Verification
8.8 Case Studies in Bridge Design
8.8 Practical Applications and Advanced Design
8.80 Conclusions and Future Trends
9.9 Introduction to Aeroelasticity: Key Concepts
9.9 Principles of Structural Design: Loads and Analysis
9.3 Aerodynamic-Structural Interaction in Bridges
9.4 Simplified Modeling and Initial Simulation
9.5 Aeroelastic Stability: Flutter and Divergence
9.6 Preliminary Design and Design Criteria
9.7 Examples of Historical Aeroelastic Failures
9.8 Structural Design Standards and Regulations
9.9 Simulation Software and Analysis Tools
9.9 Fundamentals of Structural Dynamics: Vibrations
9.9 Advanced Aeroelastic Analysis Methods
9.3 Evaluation of Structural Wind Response
9.4 Comfort Analysis: Accelerations and Vibrations
9.5 Component and Material Modeling
9.6 Case Studies: Evaluation of Existing Bridges
9.7 Vibration Mode and Natural Frequency Analysis
9.8 Design Considerations for User Comfort
9.9 Simulation Tools for Analysis Dynamic
3.9 Advanced Aeroelasticity Theory: Complex Models
3.9 Design Techniques for Flutter Mitigation
3.3 Design for Comfort: Vibration Thresholds
3.4 Wind-Structure Interaction Analysis
3.5 Damping System Design
3.6 Sensitivity Analysis and Design Optimization
3.7 Case Studies: Suspension Bridge Design
3.8 Design Considerations for Pedestrian Bridges
3.9 Simulation Software and Data Analysis
4.9 Comprehensive Aeroelastic Study Methodology
4.9 Load Analysis and Detailed Design
4.3 Comfort Evaluation: Criteria and Metrics
4.4 3D Modeling and Advanced Simulation
4.5 Performance-Based Design
4.6 Risk Analysis and Mitigation
4.7 Case Studies: Long-Span Bridges
4.8 Design Considerations for Different Environments
4.9 Model Validation and Results
5.9 Structural Design Optimization
5.9 Comfort Engineering: Strategies and Techniques
5.3 Sensitivity Analysis and Parametric Design
5.4 Vibration Control System Design
5.5 ​​Multi-Objective Optimization in Bridge Design
5.6 Case Studies: Design of Pedestrian Overpasses
5.7 Application of CAD and CAE Tools
5.8 Design for Durability and Maintenance
5.9 Implementation of Optimization in Projects
6.9 Aeroelastic Research Methodology
6.9 Experimental Design and Data Analysis
6.3 Design of Scale Models and Wind Tunnel Testing
6.4 Bridge Design: Innovations and Trends
6.5 Evaluation of New Materials and Technologies
6.6 Comfort-Based Design: Human Factors
6.7 Case Studies: Sustainable Bridges
6.8 Publication and Dissemination of Results
6.9 Research and Analysis Tools
7.9 Aeroelasticity in Footbridges: Specific Challenges
7.9 Design of Pedestrian Footbridges
7.3 Wind Response Analysis of Footbridges
7.4 Design of Damping Systems for Footbridges
7.5 Design of Aerial Bridges
7.6 Comfort Considerations in Footbridges
7.7 Case Studies: Design of Modern Footbridges
7.8 Regulations and Standards Applicable to Footbridges
7.9 Simulation and Design Validation in Footbridges
8.9 Structural Modeling for Aeroelastic Analysis
8.9 Wind Flow Simulation and Analysis
8.3 Optimization of Models and Parameters
8.4 Vibration Simulation and Comfort Analysis
8.5 Design of Experiments and Analysis of Results
8.6 Modeling of Materials and Components
8.7 Case Studies: Modeling Applications
8.8 Use of Advanced Simulation Software
8.9 Validation and Verification of Models
9.9 Wind Tunnel Testing Wind and Scale Models
9.9 Vibration Testing and Behavior Analysis
9.3 Validation of Simulation Models
9.4 Design of Experiments for Validation
9.5 Analysis of Test Data and Results
9.6 Design of Bridges and Footbridges: A Case Study
9.7 Implementation of Design Results
9.8 Test Reports and Documentation
9.9 Certification and Regulatory Compliance
9.90 Quality Assurance in Design
9.90
1.1 Introduction to Aeroelasticity in the Structural Design of Bridges and Footbridges
1.2 Fundamental Principles of Structural Dynamics Applied to Bridges
1.3 Modeling and Numerical Simulation: Finite Element Methods (FEM)
1.4 Analysis of Aerodynamic Loads: Wind and Aeroelastic Effects
1.5 Structural Design: Optimization for Strength and Comfort
1.6 Comfort Evaluation: Acceptability Criteria and Standards
1.7 Case Studies: Analysis of Existing Bridges and Footbridges
1.8 Design of a Bridge or Footbridge: Aeroelastic Considerations
1.9 Wind Tunnel Testing and Model Validation
1.10 Final Project Implementation: Report and Presentation
- 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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