Diploma in Design and Testing of Piles and Diaphragm Walls
Sobre nuestro Diploma in Design and Testing of Piles and Diaphragm Walls
The Diploma in Design and Testing of Piles and Walls focuses on the application of advanced knowledge and techniques for geotechnical design, structural analysis and field and laboratory testing related to piles and walls, fundamental in civil engineering and construction projects. The course covers geotechnical investigation, numerical modeling, and design optimization, considering factors such as bearing capacity, stability, and soil-structure interaction. The diploma program provides practical skills in conducting integrity tests (PIT, Cross-hole), load tests (static and dynamic), and analyzing results according to international standards and design codes. This program prepares professionals for the supervision, design, and analysis of deep foundations, diaphragm walls, and other retaining structures, ensuring safety and efficiency in construction. Target keywords (naturally occurring in the text): pile design, pile testing, diaphragm walls, geotechnical analysis, deep foundations, bearing capacity, numerical modeling, civil engineering.
Diploma in Design and Testing of Piles and Diaphragm Walls
- 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: 11
999 $
Competencias y resultados
Qué aprenderás
1. Structural Design and Analysis of Piles and Retaining Walls: Fundamentals and Advanced Applications
- Understand the principles of naval structural design and their application to piles and retaining walls.
- Analyze the loads and forces acting on piles and retaining walls, including their own weight, the loads of the supported structure, and environmental forces (wind, waves, currents).
- Study the different types of piles and retaining walls, their characteristics, and their specific uses in shipbuilding.
- Learn the calculation and design methods for piles and retaining walls, including stability, strength, and deformation analysis.
- Use specialized software for the design and analysis of piles and retaining walls, including 3D modeling and finite element analysis (FEA).
- Apply the acquired knowledge to solve practical problems in the design and construction of piles and retaining walls in naval projects.
- Know the international regulations and standards related to the design and construction of structures naval structures, including piles and retaining walls.
Evaluate the durability and service life of piles and retaining walls, considering the effects of corrosion, fatigue, and other environmental factors.
Implement maintenance and repair strategies for piles and retaining walls to ensure their structural integrity and extend their service life.
Develop communication and collaboration skills to work in multidisciplinary teams on naval design and construction projects.
2. Analysis and Design of Piles and Retaining Walls: Theory, Practice, and Structural Optimization
## What will you learn?
1. Fundamentals of Soil Analysis for Piles and Retaining Walls:
* Interpretation of geotechnical studies and determination of key parameters.
* Modeling of soil-structure behavior and their interactions.
* Evaluation of the bearing capacity of piles and retaining walls in different soil types.
2. Structural Design of Piles:
* Calculation of the axial and lateral bearing capacity of piles.
* Design of reinforced concrete and steel piles, including reinforcement and connections.
* Considerations for precast, driven, and drilled piles.
* Design optimization to minimize costs and maximize efficiency.
3. Structural Design of Retaining Walls:
* Stability analysis of retaining walls against sliding, overturning, and failure.
* Design of reinforced concrete retaining walls, including support elements.
* Considerations for waterproofing and drainage of retaining walls.
* Environmental impact assessment of retaining walls and mitigation measures.
4. Advanced Analysis and Design:
* Advanced numerical modeling (finite elements) to simulate the behavior of piles and retaining walls under complex loads.
* Seismic analysis and earthquake-resistant design of piles and retaining walls.
* Design of piles and retaining walls in special soils (e.g., expansive clays, liquefiable soils).
* Implementation of optimization techniques for material and cost reduction.
5. Practical Application and Case Studies:
* Real-world case studies of pile and retaining wall projects.
* Application of specialized software for analysis and design.
* Site visits and networking with industry professionals.
* Preparation of technical reports and project presentations.
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. Design and Verification of Piles and Retaining Walls: Modeling, Testing, and Comprehensive Structural Analysis
Here is the requested content:
- Study of the fundamental principles of pile and diaphragm wall design, including the selection of the appropriate foundation type according to soil conditions and applied loads.
- Mastery of advanced geotechnical and structural modeling techniques to simulate the behavior of piles and diaphragm walls under various loads and environmental conditions.
- Implementation of geotechnical tests and load tests to verify the performance and load-bearing capacity of piles and diaphragm walls, including the interpretation of results and the application of safety factors.
- Application of specialized software for the comprehensive structural analysis of piles and diaphragm walls, considering soil-structure interaction and the effects of seismicity.
- Evaluation of the durability and long-term behavior of piles and diaphragm walls, including corrosion, settlement, and other factors that may affect their service life.
- Exploration of the latest trends in the design and construction of piles and retaining walls, including the use of innovative materials and sustainable construction techniques.
Detailed analysis of retaining walls, including cast-in-place walls, diaphragms, and pile walls, with a focus on their stability, earth retention capacity, and structural behavior.
Development of effective communication skills to present the results of pile and retaining wall design and analysis to engineers, clients, and other industry professionals.
5. Pile and Diaphragm Wall Engineering: Design, Testing, Modeling, and Structural Evaluation
5. Pile and Retaining Wall Engineering: Design, Testing, Modeling, and Structural Evaluation
- Geotechnical design principles for piles and retaining walls.
- Calculation of axial and lateral load capacity of piles.
- Analysis of settlements and deformations in piles and retaining walls.
- Design of anchored and braced retaining walls.
- Selection of materials and construction methods.
- Integrity and capacity testing of piles (dynamic and static).
- Numerical modeling (FEA, finite elements) of piles and retaining walls.
- Evaluation of soil-structure interaction.
- Structural stability and safety analysis.
- Seismic considerations in design.
- Regulations and standards International.
Practical applications and case studies.
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6. Evaluation and Design of Piles and Retaining Walls: Modeling, Testing, and Geotechnical and Structural Verification
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 Design and Testing of Piles and Diaphragm Walls
Civil and Structural Engineers.
Construction, consulting, and geotechnical engineering professionals.
Experts in foundation and retaining structure design.
Engineers working on infrastructure, port, and maritime projects.
- 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 — Fundamentals and Structural Design of Piles
1.1 Introduction to Piles and Retaining Walls: Types and Applications in Naval Engineering.
1.2 Principles of Structural Design: Loads, Stresses, and Strength of Materials.
1.3 Soil Analysis: Geotechnical Properties and Their Influence on Design.
1.4 Geometric Design of Piles: Selection of Diameter, Length, and Arrangement.
1.5 Retaining Wall Design: Types, Functions, and Structural Considerations.
1.6 Design Criteria: Relevant Regulations, Codes, and Standards.
1.7 Calculation Methods: Static, Dynamic, and Load Combinations.
1.8 Design Software: Introduction to Modeling and Analysis Tools.
1.9 Practical Examples: Design of Piles and Retaining Walls in Different Scenarios.
1.10 Verification Fundamentals: Safety, Durability, and Performance.
2.2 Theory and Fundamental Concepts in Piles and Retaining Walls
2.2 Preliminary Geotechnical Design: Parameter Selection and Evaluation
2.3 Loads and Actions on Piles and Retaining Walls
2.4 Structural Analysis: Methods and Considerations
2.5 Pile Design: Bearing Capacity and Sizing
2.6 Retaining Wall Design: Stability and Strength
2.7 Numerical Modeling of Piles and Retaining Walls
2.8 Design Practice: Examples and Real-World Case Studies
2.9 Design Optimization: Costs and Efficiency
2.20 Applicable Design Codes and Standards
3.3 Fundamentals of Geotechnical and Structural Engineering for Piles and Retaining Walls
3.2 Geotechnical Design Criteria: Bearing Capacity and Settlement
3.3 Structural Design of Piles: Steel, Concrete, and Composite Materials
3.4 Structural Design of Retaining Walls: Types and Behavior
3.5 Soil-Structure Interaction: Modeling and Analysis
3.6 Optimization of Geotechnical Design: Cost and Risk Reduction
3.7 Optimization of Structural Design: Efficiency and Durability
3.8 Design Verification and Validation: Codes and Standards
3.9 Design for Different Soil Conditions: Challenges and Solutions
3.30 Case Studies: Real-World Applications and Best Practices
3.4
4.4 Geotechnical and Structural Modeling for Piles and Retaining Walls: Introduction and Fundamentals
4.2 Geotechnical and Integrity Tests for Piles: Types and Methodologies
4.3 Modeling with Specialized Software: Analysis of Piles under Axial and Lateral Loads
4.4 Structural Design of Piles: Material Selection and Dimensioning
4.5 Retaining Wall Design: Stability Analysis and Support Design
4.6 Soil-Structure Interaction Analysis: Methods and Applications
4.7 Verification and Validation of Models: Comparison with Tests and Field Data
4.8 Advanced Modeling: Pile Group Effects and Complex Loading Conditions
4.9 Evaluation of Bearing Capacity and Performance: Criteria and Standards
4.40 Case Studies: Practical Applications and Results Analysis
5. Structural Design and Pile Analysis: Fundamentals
5. Pile Analysis: Loads and Resistance
3. Structural Optimization of Piles: Material Selection
4. Structural Modeling of Piles: Software and Applications
5. Pile Engineering: Design and Execution
6. Pile Evaluation: Testing and Analysis
7. Pile Design: Methodologies and Criteria
8. Comprehensive Pile Design and Analysis: Optimization and Verification
6.6 Fundamentals of Structural and Geotechnical Design
6.2 Loads and Stresses in Piles and Shear Walls
6.3 Soil Analysis and Geotechnical Parameters
6.4 Design of Individual and Grouped Piles
6.5 Design of Structural Shear Walls
6.6 Advanced Applications: Special Foundations
6.7 Structural Design and Analysis Software
6.8 Case Studies: Real-World Projects
6.9 Design Codes and Standards
6.60 Sustainability Aspects in Structural Design
2.6 Soil-Structure Interaction Theory
2.2 Design Methods for Piles and Shear Walls
2.3 Bearing Capacity and Settlements
2.4 Ultimate Limit State (ULS) Design 2.5 Serviceability Limit State (SLS) Design.
2.6 Seismic Design of Piles and Retaining Walls.
2.7 Practice: Design and Calculation Exercises.
2.8 Structural Optimization: Material Selection.
2.9 Structural Optimization: Sizing.
2.60 Reinforcement Design in Concrete Elements.
3.6 Geotechnical Design Criteria.
3.2 Structural Design Criteria.
3.3 Bearing Capacity Verification.
3.4 Stability Verification.
3.5 Deformation Verification.
3.6 Performance-Based Design.
3.7 Design Optimization: Cost-Benefit Analysis.
3.8 Design Optimization: Environmental Aspects.
3.9 Case Studies: Comparative Analysis. 3.60 Innovative Design Methodologies
4.6 Structural Modeling with Specialized Software
4.2 Static and Dynamic Analysis of Piles
4.3 Structural Analysis of Retaining Walls
4.4 Pile Load Testing: Methods and Procedures
4.5 Interpretation of Test Results
4.6 Calibration of Structural Models
4.7 Advanced Soil-Structure Interaction Analysis
4.8 Verification of Results and Design Validation
4.9 Sensitivity Analysis and Design Optimization
4.60 Design of Construction Details
5.6 Conceptual Design of Deep Foundations
5.2 Selection of Pile and Retaining Wall Type
5.3 Construction Methods and Quality Control
5.4 Integrity and Bearing Capacity Tests
5.5 Advanced Numerical Modeling
5.6 Seismic Response Assessment
5.7 Failure Analysis and Risk Assessment
5.8 Reinforcement and Connection Design
5.9 Durability and Service Life Assessment
5.60 Health and Safety Aspects in Design
6.6 Geotechnical and Structural Modeling
6.2 Field and Laboratory Testing
6.3 Bearing Capacity Verification
6.4 Settlement Verification
6.5 Design of Piles Subjected to Horizontal Loads
6.6 Design of Piles in Complex Soils
6.7 Design of Anchored Retaining Walls
6.8 Slope Stability Analysis
6.9 Implementation of Soil Improvements 6.60 Design Verification with Software
7.6 Testing Methodologies for Piles and Retaining Walls
7.2 Test Data Analysis
7.3 Design with Dynamic and Static Tests
7.4 Test Results Analysis
7.5 Structural Optimization Based on Tests
7.6 Geotechnical Design Optimization
7.7 Foundation Design on Unfavorable Soils
7.8 Design for Risk Mitigation
7.9 Case Studies
7.60 Design for Sustainability and Cost Reduction
8.6 Selection of Construction Methods
8.2 Pile Design in Different Soil Types
8.3 Static and Dynamic Load Tests 8.4 Interpretation of Test Results
8.5 Soil-Structure Interaction Analysis
8.6 Optimization of Pile Design
8.7 Design of Supported Retaining Walls
8.8 Structural and Geotechnical Verification
8.9 Integration of Test Results and Modeling
8.60 Design for Durability and Maintenance
7.7 Fundamentals of Structural Design: Loads, Standards, and Materials
7.2 Pile Analysis: Static and Dynamic Methods
7.3 Pile Design: Design Criteria and Sizing
7.4 Retaining Wall Analysis: Theory and Calculation Methods
7.7 Structural Design of Retaining Walls: Stability and Strength
7.6 Advanced Applications: Complex Soils and Special Conditions
7.7 Structural Analysis Software: Introduction and Applications
2.7 Pile Theory: Soil-Structure Behavior
2.2 Pile Design: Loads and Actions, Sizing
2.3 Retaining Wall Analysis: Earth Pressure and Design
2.4 Geotechnical Modeling: Soil Parameters and Analysis
2.7 Structural Modeling: Finite Elements and Analysis
2.6 Practice: Design and Analysis Examples
2.7 Structural Optimization: Cost and Resource Reduction
3.7 Design Criteria Geotechnical Engineering: Bearing Capacity and Settlements
3.2 Structural Design Criteria: Strength and Stability
3.3 Pile Optimization: Diameter, Length, and Arrangement
3.4 Retaining Wall Optimization: Thickness, Reinforcement, and Anchors
3.7 Pile Verification: Loads and Strength
3.6 Retaining Wall Verification: Global and Local Stability
3.7 Case Studies: Application of the Criteria
4.7 Pile Modeling: Software and Advanced Techniques
4.2 Retaining Wall Modeling: Analysis and Simulation
4.3 Pile Load Testing: Methods and Interpretation
4.4 Structural Analysis: Results and Verification
4.7 Comprehensive Analysis: Soil-Structure Interaction
4.6 Seismic Design of Piles and Retaining Walls
4.7 Practical Cases and Applications
7.7 Pile Design: Selection and Sizing
7.2 Retaining Wall Design: Stability and Strength
7.3 Pile Testing: Methods and Results
7.4 Geotechnical Modeling: Soil-Structure Interaction
7.7 Structural Modeling: Finite Element Analysis
7.6 Structural Evaluation: Verification and Optimization
7.7 Real-World Case Studies
7.8 Regulatory and Normative Aspects
6.7 Geotechnical Modeling: Parameters and Analysis
6.2 Structural Modeling: Software and Methodology
6.3 Load Tests: Interpretation of Results
6.4 Geotechnical Verification: Bearing Capacity and Settlements
6.7 Structural Verification: Strength and Stability
6.6 Pile and Retaining Wall Design: Model Adaptation
6.7 Case Studies: Real-World Applications
7.7 Testing Methodologies: Design and Execution
7.2 Test Analysis: Interpretation of Results
7.3 Pile Design: Criteria and Dimensioning
7.4 Retaining Wall Design: Earth Pressure Earthworks and Stability
7.7 Structural Optimization: Pile Design
7.6 Structural Optimization: Retaining Wall Design
7.7 Case Studies: Design and Evaluation
8.7 Pile Design: Loads and Actions
8.2 Retaining Wall Design: Structural Analysis
8.3 Pile Testing: Methods and Results
8.4 Structural Analysis: Methods and Software
8.7 Optimization: Geotechnical and Structural
8.6 Comprehensive Verification: Safety and Cost-Effectiveness
8.7 Case Studies: Practical Applications
8.7
8.8 Introduction to Pile and Retaining Wall Design: Fundamentals and Scope
8.8 Geotechnical Engineering for Piles and Retaining Walls: Soil Studies and Characterization
8.3 Structural Design of Piles: Loads, Materials, and Criteria
8.4 Structural Design of Retaining Walls: Types, Methods, and Analysis
8.5 Pile Testing: Types, Interpretation, and Applications
8.6 Structural Modeling and Analysis: Software and Advanced Techniques
8.7 Design Verification: Criteria, Standards, and Safety
8.8 Design Optimization: Geotechnical and Structural Aspects
8.8 Practical Cases: Real-World Applications and Case Studies
8.80 Conclusions and Future Trends in Pile and Retaining Wall Design
9.9 Fundamentals of structural and geotechnical engineering applied to piles.
9.9 Loads and actions: static and dynamic load analysis.
9.3 Pile design: selection of pile type and materials.
9.4 Bearing capacity analysis: geotechnical and structural methods.
9.5 Retaining wall design: typologies and structural considerations.
9.6 Soil-structure interaction: modeling and analysis.
9.7 Advanced applications: piles in special soils and retaining walls in complex environments.
9.8 Design software: introduction and practical examples.
9.9 Regulations and standards: compliance and application.
9.90 Case studies: analysis of successful designs and lessons learned.
9.9 Review of the theoretical principles of pile and retaining wall design.
9.9 Analysis methods: static, kinematic, and dynamic. 9.3 Bearing Capacity Design: Geotechnical and Structural Approaches
9.4 Settlement Design: Analysis and Prediction
9.5 Retaining Wall Design: Stability and Deformation
9.6 Structural Optimization: Design Criteria and Material Selection
9.7 Seismic Analysis: Considerations in the Design of Piles and Retaining Walls
9.8 Analysis Software: Modeling and Simulation
9.9 Design Practice: Exercises and Solved Problems
9.90 Case Studies: Design and Analysis of Real-World Projects
3.9 Geotechnical Design Criteria: Bearing Capacity, Settlement, and Stability
3.9 Structural Design Criteria: Strength, Stiffness, and Durability
3.3 Optimization of Pile and Retaining Wall Geometry and Materials
3.4 Verification of Bearing Capacity and Stability
3.5 Verification of Structural Safety: Flexural, Shear, and Compressive Strength 3.6 Design for Durability: Protection against Corrosion and Degradation
3.7 Numerical Modeling for Optimization: Parametric Analysis
3.8 Cost-Benefit Analysis: Selection of the Optimal Solution
3.9 Regulations and Standards: Requirements and Recommendations
3.90 Case Studies: Examples of Successful Optimization
4.9 Pile and Shear Wall Modeling: Methods and Tools
4.9 Types of Tests: Static and Dynamic Load Tests
4.3 Test Interpretation: Analysis of Results and Model Calibration
4.4 Structural Analysis: Finite Elements and Other Methods
4.5 Seismic Design: Considerations and Analysis
4.6 Verification of Bearing Capacity and Deformations
4.7 Soil-Structure Interaction Analysis
4.8 Structural Analysis Software: Applications and Examples
4.9 Case Studies: Modeling, Testing, and Analysis of Real-World Projects 4.90 Comprehensive Design: Integration of Modeling, Testing, and Structural Analysis
5.9 Principles of Pile and Shear Wall Engineering
5.9 Selection of Pile and Shear Wall Type
5.3 Geotechnical and Structural Design: Specific Considerations
5.4 Field Testing: Load Tests and Integrity Tests
5.5 Numerical Modeling: Analysis and Simulation
5.6 Structural Evaluation: Stress and Strain Analysis
5.7 Evaluation of Bearing Capacity and Settlements
5.8 Design for Special Conditions: Problematic Soils and Seismic Loads
5.9 Case Studies: Landmark Projects and Lessons Learned
5.90 Comprehensive Design: Integration of All Engineering Aspects
6.9 Geotechnical Modeling: Methods and Tools
6.9 Structural Modeling: Finite Element Analysis and Other Methods 6.3 Field Tests: Interpretation and Analysis of Results
6.4 Geotechnical Verification: Bearing Capacity, Settlements, and Stability
6.5 Structural Verification: Strength, Stiffness, and Durability
6.6 Seismic Design: Analysis and Considerations
6.7 Design for Special Conditions: Expansive Soils, Liquefaction, and Others
6.8 Regulations and Standards: Compliance and Application
6.9 Case Studies: Real-World Projects and Failure Analysis
6.90 Design Optimization: Criteria and Methodologies
7.9 Testing Methodologies for Piles and Retaining Walls
7.9 Static Load Tests: Procedures and Analysis
7.3 Dynamic Load Tests: Methods and Applications
7.4 Integrity Tests: Seismic and Other Methods
7.5 Structural Analysis: Finite Element Methods 7.6 Bearing Capacity Analysis: Geotechnical and Structural Methods
7.7 Structural Optimization: Design Criteria and Material Selection
7.8 Seismic Design: Considerations and Analysis
7.9 Case Studies: Application of Methodologies in Real-World Projects
7.90 Comparative Evaluation: Advantages and Disadvantages of Different Methodologies
8.9 Geotechnical Design: Bearing Capacity and Settlements
8.9 Structural Design: Strength, Stiffness, and Durability
8.3 Field Tests: Load Tests and Integrity Tests
8.4 Results Analysis: Interpretation and Calibration of Models
8.5 Numerical Modeling: Finite Element Analysis
8.6 Design Optimization: Material and Geometry Selection
8.7 Safety Verification: Compliance with Regulations and Standards
8.8 Design for Special Conditions: Problematic Soils and Seismic Loads 8.9 Case studies: design, testing, and analysis in real-world projects.
8.90 Integrated design: integration of all aspects of the project.
1.1 Fundamentals of Geotechnical and Structural Engineering in Piles and Retaining Walls
1.2 Loads and Actions: Determination and Modeling for Design
1.3 Structural Design of Piles: Materials, Dimensioning, and Reinforcement
1.4 Structural Design of Retaining Walls: Types, Support Systems, and Stability
1.5 Pile Analysis: Static and Dynamic Methods
1.6 Retaining Wall Analysis: Finite Element Methods and Performance-Based Design
1.7 Design and Modeling Software: Practical Applications
1.8 Verification and Quality Control in Construction
1.8
- 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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