Diploma in Structural Diagnosis and In Situ Testing
Sobre nuestro Diploma in Structural Diagnosis and In Situ Testing
The Diploma in Structural Diagnostics and In-Situ Testing trains students in the evaluation and analysis of structural integrity, using advanced non-destructive testing (NDT) techniques and structural diagnostic methods applied to building and civil engineering projects. It focuses on the identification and assessment of damage in existing structures, such as reinforced concrete, steel, and masonry, through the use of technologies such as ultrasound, sclerometer testing, and vibration analysis. The program covers the application of regulations and standards for structural inspection, repair, and reinforcement, including the interpretation of results and the preparation of technical reports. The program provides practical skills for conducting on-site inspections, interpreting test data, and proposing structural rehabilitation and reinforcement solutions, preparing professionals for roles such as inspection engineers, structural consultants, and building pathology specialists. It delves into the understanding of common pathologies, such as cracking, corrosion, and material degradation, and the design of efficient and sustainable rehabilitation solutions. Target keywords (natural occurrences in the text): structural diagnosis, non-destructive testing, reinforced concrete, building pathology, structural inspection, structural rehabilitation, vibration analysis, diploma in structures.
Diploma in Structural Diagnosis and In Situ Testing
- 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: 3
995 $
Competencias y resultados
Qué aprenderás
1. Mastery of Naval Structural Diagnostics: In-Situ Testing and Advanced Analysis
- Evaluation of the structural response of ships using finite element analysis (FEA) models.
- Application of non-destructive testing (NDT), including ultrasonic testing (UT), radiography (RT), and thermography.
- Identification and analysis of failure modes in naval structures, such as buckling, sagging, and fatigue.
2. Specialization in Naval Structural Diagnostics: Advanced Techniques and In-Situ Evaluation
- In-depth analysis of advanced structural failure modes, including the identification and evaluation of complex couplings such as flap-lag-torsion, whirl flutter, and fatigue analysis in naval components.
- Master the design techniques for composite shell structures, applying finite element (FE) analysis for the design of components in composites, paying special attention to joints and bonded joints, ensuring structural integrity and material optimization.
- Apply damage tolerance methodologies for the service life management of naval structures, along with the advanced use of non-destructive testing (NDT) techniques, such as Ultrasonic Testing (UT), Radiography (RT), and Thermography, for damage detection and structural integrity assessment.
situ*.
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. Naval Structural Evaluation: In-Situ Testing, Diagnosis, and In-Depth Analysis
4. Naval Structural Evaluation: In Situ Testing, Diagnosis, and In-Depth Analysis
- Interpret and apply methodologies for the analysis of structural damage in naval components.
- Master non-destructive testing (NDT) techniques, including ultrasonic testing (UT), radiography (RT), and infrared thermography.
- Perform accurate diagnoses using finite element analysis (FEA) to evaluate structural integrity.
- Evaluate fatigue resistance and damage tolerance in naval structures.
- Understand and analyze the behavior of composite materials in marine environments, including the evaluation of adhesive bonds.
- Identify and analyze structural failure modes, such as buckling and Buckling.
Apply knowledge to the evaluation of structures subjected to dynamic and cyclic loads.
Use specialized software to simulate and analyze structural behavior under various loading conditions.
Analyze flap-lag-torsion, whirl flutter, and fatigue couplings.
Design laminates in composites, joints, and bonded joints with FE.
Implement damage tolerance and NDT (UT/RT/thermography).
5. Naval Structural Diagnostics: In-Situ Testing, Damage Assessment, and Integrity Analysis
5. **Naval Structural Diagnostics: In-Situ Testing, Damage Assessment, and Integrity Analysis**
- Identify and evaluate the causes of failure in naval structures, including analysis of material degradation and corrosion.
- Apply non-destructive testing (NDT) techniques such as ultrasonic testing (UT), radiography (RT), thermography, and magnetic particle inspection (MPI) for defect detection.
- Interpret NDT results for damage assessment and structural integrity determination.
- Perform fatigue and cumulative damage analyses on critical components.
- Understand and apply international standards and regulations for the inspection and evaluation of naval structures.
- Use structural analysis (FEA) software to simulate the behavior of damaged structures.
and predict its remaining service life.
Develop inspection and maintenance plans based on the condition of the structure and the results of the analyses.
Evaluate the structural integrity of different types of vessels and offshore platforms.
Analyze the impact of environmental loads (waves, wind, temperature) on the integrity of structures.
Understand the principles of repair and reinforcement of damaged structures, including the selection of appropriate materials and techniques.
6. Naval Structural Evaluation: In-Situ Testing, Diagnosis, and Failure Analysis
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 Structural Diagnosis and In Situ Testing
- Engineers with degrees in Naval Engineering, Civil Engineering, Structural Engineering, or related fields.
- Professionals in the naval industry, shipyards, and inspection and certification companies.
- Technicians and specialists in structural diagnostics, non-destructive testing, and naval maintenance.
- Inspectors, auditors, and maritime safety personnel seeking to update their knowledge.
Recommended requirements: Basic knowledge of strength of materials, fluid mechanics, and naval design; ES/EN B2+/C1 level.
- 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 Naval Structural Diagnostics**
1.1 Importance of Naval Structural Diagnostics: Fundamentals and Scope.
1.2 Principles of Naval Structure: Design, Materials, and Loads.
1.3 Methodology of Structural Diagnostics: Approach and Objectives.
1.4 Regulations and Standards: Ship Classification and Regulations.
1.5 Types of Structural Failures: Damage Mechanisms and Failure Modes.
1.6 Introduction to In-Situ Testing: Types and Applications.
1.7 Visual Inspection Techniques: Methodology and Documentation.
1.8 Basic Tools and Equipment: Selection and Use.
1.9 Introduction to Data Analysis: Interpretation and Initial Evaluation.
1.10 Case Studies: Practical Examples of Structural Diagnostics.
2.2 Fundamentals of in-situ inspection of naval structures.
2.2 Advanced visual inspection techniques.
2.3 Applied non-destructive testing (NDT): ultrasound, magnetic particle testing, and penetrant testing.
2.4 Analysis of NDT data and results.
2.5 Evaluation of corrosion and its effects on the structure.
2.6 Modeling and simulation of naval structures.
2.7 Analysis of stresses and strains in structures.
2.8 Evaluation of structural integrity and remaining service life.
2.9 Preparation of technical reports and recommendations.
2.20 Practical examples and case studies of naval structural diagnosis.
3.3 Introduction to Naval Structural Diagnostics and Its Importance
3.2 Relevant International Standards and Regulations
3.3 Types of Naval Structures and Their Components
3.4 Common Materials in Shipbuilding and Their Properties
3.5 Fundamentals of Corrosion and Degradation in Naval Structures
3.6 Occupational Health and Safety in Naval Diagnostics
3.7 Documentation and Information Management in Naval Inspections
3.8 Principles of Welding and Their Structural Implications
3.9 Interpretation of Naval Drawings and Technical Specifications
3.30 Legal and Regulatory Framework in the Maritime Sector
2.3 Introduction to Non-Destructive Testing (NDT)
2.2 NDT Techniques: Visual Inspection, Penetrant Testing, Magnetic Particle Testing
2.3 NDT Techniques: Ultrasonic Testing, Radiography, Eddy Current Testing
2.4 Application of NDT in Detecting Defects in Naval Structures
2.5 Evaluation of Structural Integrity Based on NDT Results
2.6 Acceptance and Rejection Criteria According to Standards
2.7 Evaluation of Corrosion Using NDT Techniques
2.8 Interpretation and Analysis of Non-Destructive Testing Results
2.9 Design of NDT-Based Inspection Programs
2.30 Practical Applications of NDT in the Naval Industry
3.3 Introduction to Naval Structural Analysis
3.2 Principles of Structural Mechanics and Strength of Materials
3.3 Modeling and Numerical Simulation of Naval Structures
3.4 Finite Element Analysis (FEA) Applied to Naval Structures
3.5 Loads and Loading Conditions in Naval Structures
3.6 Stress, Strain, and Structural Stability Analysis
3.7 Fatigue and Service Life Assessment of Structures
3.8 Structural Integrity Assessment Based on Analysis
3.9 Integration of NDT and Structural Analysis Results
3.30 Technical Reports and Documentation of Structural Analysis
4.3 Introduction to In-Situ Testing in Naval Diagnostics
4.2 In-Situ Testing Techniques: Thickness Measurement, Hardness, etc.
4.3 In-situ testing techniques: vibration analysis, load testing
4.4 Planning and execution of in-situ tests in naval environments
4.5 In-situ corrosion diagnosis of naval structures
4.6 In-situ weld integrity assessment
4.7 Advanced techniques for analyzing data obtained in-situ
4.8 Interpretation of results and report writing
4.9 Safety and risk mitigation in in-situ testing
4.30 Practical cases of advanced naval diagnostics
5.3 Identification and classification of structural damage
5.2 Assessment of damage severity and its causes
5.3 Damage diagnostic techniques: visual inspection, NDT, etc.
5.3 5.4 Analysis of Crack Propagation and Structural Failures
5.5 Post-Damage Structural Integrity Assessment
5.6 Repair and Reinforcement Methodologies for Damaged Structures
5.7 Risk Analysis and Structural Safety Management
5.8 Preparation of Damage Assessment Reports
5.9 Damage Assessment Case Studies and Solutions
5.30 Failure Analysis and Lessons Learned
6.3 Introduction to Structural Failure Analysis
6.2 Failure Investigation Methodology
6.3 Data Collection and Analysis in Failure Analysis
6.4 Identification of the Root Causes of Structural Failures
6.5 Failure Mode and Effects Analysis (FMEA) in Naval Structures
6.6 Evaluation of Structural Safety and Reliability
6.7 Preparation of Failure Analysis Reports
6.8 Recommendations for Failure Prevention
6.9 Failure Analysis Case Studies in Naval Structures
6.30 Legal Aspects and Liability in Failure Analysis Failures
7.3 Introduction to Cutting-Edge Techniques in Structural Diagnostics
7.2 Advanced NDT Techniques: Phased Array, TOFD, etc.
7.3 Sensors and Real-Time Structural Monitoring Systems
7.4 Application of Artificial Intelligence in Naval Diagnostics
7.5 Use of Drones and Robots in Structural Inspection
7.6 Cutting-Edge Data Analysis Techniques
7.7 Advanced Modeling and Simulation of Naval Structures
7.8 New Materials and Technologies in Shipbuilding
7.9 Implementation of Cutting-Edge Techniques in Practice
7.30 Future Trends in Naval Structural Diagnostics
8.3 Inspection of Naval Structures: Hull, Decks, Bulkheads, etc.
8.2 Hull Structural Integrity Assessment
8.3 Global and Local Structural Stability Analysis
8.4 Corrosion and Degradation Assessment in Different Environments
8.5 Weld and Structural Joint Assessment
8.6 Integration of In-Situ and NDT Test Data
8.7 Risk Analysis and Structural Safety Management
8.8 Preparation of Comprehensive Assessment Reports
8.9 Case Studies of Comprehensive Structural Assessment and Analysis
8.30 Maintenance and Repair Recommendations
4.4 Fundamentals of Naval Structural Diagnostics: Introduction and Scope
4.2 In-Situ Testing: Visual Inspection and Basic Techniques
4.3 Common Non-Destructive Testing (NDT) Techniques in Naval Diagnostics
4.4 Evaluation of Corrosion and Degradation of Materials
4.5 Damage and Failure Analysis in Naval Structures
4.6 Interpretation of Results and Preparation of Technical Reports
4.7 Tools and Software for Structural Analysis
4.8 Case Studies: Diagnosis of Real Naval Structures
4.9 Regulations and Standards in Naval Structural Diagnostics
4.40 Safety Considerations and Risk Management in In-Situ Testing
4.5
5.5 Fundamentals of Naval Structural Diagnosis
5.5 Naval Design Standards and Codes
5.3 Materials in Shipbuilding: Properties and Degradation
5.4 Introduction to Structural Testing: Types and Applications
5.5 Interpretation of Naval Drawings and Technical Documentation
5.6 Introduction to Corrosion and its Effects on Naval Structures
5.7 Safety in Naval Structural Inspections
5.5 In-Situ Testing: Principles and Methodologies
5.5 Advanced Visual Inspection Techniques: Lighting and Equipment
5.3 Ultrasound: Applications and Data Analysis
5.4 Radiography: Principles, Safety, and Applications
5.5 Strain Measurement Techniques: Extensometers and Strain Gauges
5.6 Vibration Analysis in Naval Structures
5.7 Load Testing on Naval Structures: Methodology and Analysis
3.5 Non-Destructive Testing: Introduction and Scope
3.5 Penetrant Testing: Methodology and Applications
3.3 Magnetic Particle Testing: Principles and Applications
3.4 Acoustic Testing: Principles and Applications in Naval Structures
3.5 Structural Integrity Analysis using Advanced Ultrasound
3.6 Comprehensive Corrosion Assessment: Techniques and Data Analysis
3.7 Preparation of Non-Destructive Testing Reports: Standards and Documentation
4.5 Selection of In-Situ Tests According to the Type of Naval Structure
4.5 Structural Diagnostic Methodology: Planning and Execution
4.3 Interpretation of In-Situ and Non-Destructive Testing Results
4.4 Data Analysis and Structural Integrity Assessment
4.5 Acceptance and Rejection Criteria: Regulations and Standards
4.6 Preparation of Structural Assessment Reports: Content and Format
4.7 Case Studies Practical Exercises: Structural Assessment in Different Types of Vessels
5.5 Identification and Classification of Structural Damage
5.5 Failure Mechanisms in Naval Structures
5.3 Crack Propagation Analysis
5.4 Post-Damage Structural Integrity Assessment
5.5 Damage Repair Techniques: Selection and Application
5.6 Structural Risk and Safety Analysis
5.7 Case Studies: Damage Analysis and Repairs in Vessels
6.5 Types of Structural Failures: Causes and Consequences
6.5 Failure Analysis Methodology: Research and Data Collection
6.3 Root Cause Analysis of Structural Failures
6.4 Assessment of Failure Severity and its Impact on Safety
6.5 Failure Analysis Techniques: Ishikawa Diagrams, Fault Trees
6.6 Recommendations for Preventing Future Failures
6.7 Case Studies Study: Failure Analysis in Different Types of Naval Structures
7.5 Infrared Thermography Techniques in Naval Diagnostics
7.5 Guided Wave Inspection: Principles and Applications
7.3 Acoustic Cameras: Leak and Fault Detection
7.4 3D Laser Scanning for Structural Evaluation
7.5 Remote Sensors and Continuous Monitoring of Naval Structures
7.6 Artificial Intelligence in Diagnostic Data Analysis
7.7 Augmented Reality Applications in Naval Inspections
8.5 Selection of Comprehensive Evaluation Techniques According to Vessel Type
8.5 Evaluation of the Residual Strength of Naval Structures
8.3 Finite Element Modeling and Simulation in Structural Diagnostics
8.4 Optimization of the Maintenance Plan Based on the Diagnosis
8.5 Cost-Benefit Analysis of Diagnostic Techniques
8.6 Structural Information Management: Databases and Software
8.7 Success Stories: Application of Comprehensive Assessment in the Shipbuilding Industry
6.6 Introduction to Naval Structural Failure Analysis
6.2 In-Situ Testing Methodologies for Structural Evaluation
6.3 Identification and Characterization of Damage in Naval Structures
6.4 Failure Mode and Damage Mechanism Analysis
6.5 Application of Non-Destructive Testing (NDT) in Diagnosis
6.6 Interpretation and Evaluation of NDT Results
6.7 Structural Integrity Analysis and Acceptance Criteria
6.8 Evaluation of the Severity and Consequences of Failures
6.9 Design of Structural Repairs and Reinforcements
6.60 Case Studies: Failure Analysis in Naval Structures
6.7
7.7 Introduction to Naval Structural Diagnostics: Key Concepts
7.2 Types of Naval Structures and Their Characteristics
7.3 Regulations and Standards in Structural Diagnostics
7.4 Basic Diagnostic Tools and Equipment
7.7 Workplace Safety and Environmental Protection
2.7 In-Situ Testing: Methodologies and Applications
2.2 Advanced Measurement and Analysis Techniques
2.3 Vibration Analysis and Its Implications
2.4 Ultrasound Techniques and Their Applications in Diagnostics
2.7 Design of In-Situ Testing Protocols
3.7 Introduction to Non-Destructive Testing (NDT)
3.2 NDT: Industrial Radiography and Its Applications
3.3 NDT: Liquid Penetrant Testing
3.4 NDT: Magnetic Particle Testing
3.7 Comprehensive Evaluation: Integration of NDT Results and Evaluation Criteria
4.7 Structural Evaluation: Fundamentals and Objectives
4.2 In-Situ Testing: Load and Deformation Tests
4.3 Corrosion and Material Degradation Diagnosis
4.4 Data Analysis: Interpretation and Evaluation of Results
4.7 Preparation of Technical Reports and Recommendations
7.7 Common Types of Structural Damage in Naval Structures
7.2 Structural Integrity Analysis
7.3 Crack and Fissure Assessment
7.4 Fatigue and Remaining Service Life Analysis
7.7 Repair and Reinforcement Planning
6.7 Failure Analysis: Methodology and Approach
6.2 Case Studies: Failure Identification and Analysis
6.3 Corrosion and Degradation Failures
6.4 Overload and Impact Failures
6.7 Failure Mitigation and Prevention Strategies
7.7 Cutting-Edge Techniques in Naval Diagnostics
7.2 Remote Inspection: Drones and Robots
7.3 Intelligent Sensors and Continuous Monitoring
7.4 Modeling and Simulation of Naval Structures
7.7 Innovations in Materials and Repair Technologies
8.7 Comprehensive Assessment: A Holistic Approach
8.2 Risk Analysis and Prioritization of Interventions
8.3 Remaining Useful Life (RUL) Assessment
8.4 Maintenance Planning and Asset Management
8.7 Case Studies: Comprehensive Assessment and Analysis of Structures
8.7
8.8 Fundamentals of Naval Structural Engineering: Principles and Regulations
8.8 In-Situ Testing: Inspection Techniques and Visual Evaluation
8.3 Non-Destructive Testing (NDT) Applied to Naval Structures
8.4 Damage and Failure Analysis in Naval Structures
8.5 Structural Integrity Assessment: Methods and Criteria
8.6 Structural Modeling and Simulation: Finite Element Analysis (FEA)
8.7 Design and Material Selection: Criteria for the Naval Industry
8.8 Service Life Assessment and Predictive Maintenance
8.8 International Standards and Regulations for Structural Evaluation
8.80 Case Studies: Failure Analysis and Lessons Learned
9.9 Fundamentals of Naval Structural Diagnostics: Key concepts and terminology.
9.9 Importance of In-Situ Testing: Advantages and applications in naval structures.
9.3 Types of In-Situ Testing: Visual inspection, load testing, and thickness measurement.
9.4 Data Collection and Analysis: Interpretation of results and reporting of findings.
9.5 Introduction to legislation and regulations: Compliance in the naval sector.
9.9 Advanced Ultrasound: Phased Array and TOFD techniques for defect detection.
9.9 Digital Radiography: Principles, applications, and image analysis in naval structures.
9.3 Infrared Thermography: Detection of thermal anomalies and integrity assessment.
9.4 Vibration Analysis: Machinery monitoring and detection of incipient failures. 9.5 Corrosion Assessment Techniques: Corrosion Rate Measurement and Cathodic Protection
3.9 Principles of Non-Destructive Testing (NDT): Advantages and Limitations
3.9 Ultrasound-Based NDT: Applications and Specific Techniques
3.3 Magnetic Particle Inspection: Detection of Surface and Subsurface Discontinuities
3.4 Liquid Penetrant Testing: Detection of Surface Defects in Materials
3.5 Evaluation of Results: Acceptance and Rejection Criteria, Evaluation Reports
4.9 Planning and Preparation for In-Situ Testing: Selection of Techniques and Equipment
4.9 Evaluation Methodologies: Visual Inspection, Tensile Testing, and Deformation Analysis
4.3 In-Situ Data Analysis: Software and Structural Simulation Tools
4.4 Evaluation of Structural Integrity: Evaluation Criteria and Recommendations 4.5 Preparation of technical reports: Documentation of findings and conclusions.
5.9 Types of structural damage: Corrosion, fatigue, and overloading.
5.9 Corrosion assessment: Measurement and analysis techniques.
5.3 Fatigue analysis: Modeling and simulation of structural behavior.
5.4 Integrity analysis: Evaluation of residual load-bearing capacity.
5.5 Case studies: Failure analysis and corrective measures.
6.9 Failure analysis: Methodology, steps, and tools.
6.9 Root cause identification: Cause-and-effect analysis and Ishikawa diagram.
6.3 Failure modes and effects analysis (FMEA): Application to naval structures.
6.4 Failure evaluation: Acceptance and rejection criteria.
6.5 Design and evaluation of solutions: Repair and prevention of failures.
7.9 Advanced sensors: Monitoring and remote sensing technologies. 7.9 Artificial intelligence and machine learning: Application in structural diagnostics.
7.3 Drones and robotics: Inspection in hard-to-reach areas.
7.4 3D modeling and augmented reality: Data visualization and analysis.
7.5 Data integration: Platforms and information management systems.
8.9 Comprehensive evaluation methodology: Planning and scope.
8.9 Risk assessment: Identification and analysis of risks in naval structures.
8.3 Life cycle analysis: Design, construction, operation, and maintenance.
8.4 Cost-benefit analysis: Profitability of proposed solutions.
8.5 Reporting and recommendations: Effective communication of results.
1. Introduction to Naval Structural Inspection and Diagnosis
2. Fundamentals of Non-Destructive Testing (NDT) Applied to Naval Structures
3. In-Situ Testing Techniques: Ultrasonic, Magnetic Particle, and Liquid Penetrant Testing
4. Interpretation and Analysis of NDT Results
5. Structural Integrity Assessment and Damage Determination
6. Structural Modeling and Simulation: Finite Element Analysis (FEA)
7. Failure Mode Analysis and Acceptance Criteria
8. Design and Execution of Structural Inspections
9. Preparation of Technical Reports and Recommendations
10. Case Studies: Failure Analysis and Engineering Solutions
- 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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