Diploma in Seismic Rehabilitation and Vulnerability
Sobre nuestro Diploma in Seismic Rehabilitation and Vulnerability
The Diploma in Seismic Rehabilitation and Vulnerability focuses on the application of advanced techniques for the evaluation, design, and execution of rehabilitation projects for existing structures in the face of earthquakes. It includes the analysis of the seismic vulnerability of buildings, the study of structural damage, and the development of strategies for structural reinforcement, using seismic codes and advanced structural modeling. It addresses the repair of concrete, masonry, and steel structures, considering aspects such as durability and seismic behavior. The program aims to provide the tools to assess and mitigate seismic risk, improve the safety of buildings, and optimize investment in rehabilitation projects. The diploma program includes practical case studies and site visits to understand different structural intervention methodologies and the selection of reinforcement materials and techniques. It delves into the evaluation of the load-bearing capacity of structures and the design of reinforcement solutions that meet seismic safety requirements. Participants acquire skills in using specialized software for seismic analysis and reinforcement design, preparing them for professional roles in structural engineering and rehabilitation project management.
Target keywords (naturally occurring in the text): seismic rehabilitation, seismic vulnerability, structural reinforcement, structural damage, seismic regulations, structural modeling, structural repair, structural engineering.
Diploma in Seismic Rehabilitation and Vulnerability
- 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
875 $
Competencias y resultados
Qué aprenderás
1. **Seismic Risk Assessment and Mitigation: A Comprehensive Diploma Program**
## What Will You Learn in the Diploma in Seismic Risk Assessment and Mitigation?
Through this comprehensive diploma program, you will acquire specialized knowledge and skills to understand, assess, and mitigate the risks associated with seismic activity. The program will provide you with a solid foundation in the latest techniques and methodologies, enabling you to develop effective solutions for infrastructure protection and the safety of people.
Here are the key points you will master:
1. **Fundamentals of Seismology and Earthquake Engineering:**
* You will understand the fundamental principles of seismology, including the generation and propagation of seismic waves.
* You will learn to interpret seismic hazard maps and assess seismic threat in different regions.
* You will become familiar with key concepts in earthquake engineering, such as the seismic response of structures and failure mechanisms.
2. **Seismic Risk Assessment:**
* You will master the methodologies for seismic risk assessment, including the identification and characterization of seismic sources, the determination of seismic hazard, and the evaluation of the seismic vulnerability of structures.
* You will learn to use specialized software for seismic analysis and simulation of structural behavior during seismic events.
* You will develop the ability to conduct seismic microzonation studies and evaluate the impact of soil amplification on the response of structures.
3. **Seismic Risk Mitigation:**
* You will learn about different seismic mitigation strategies, including the earthquake-resistant design of new structures and the rehabilitation and strengthening of existing structures.
* You will learn to select and apply earthquake-resistant design techniques, such as the use of dampers, seismic isolators, and vibration control systems. * You will develop the ability to design and supervise seismic rehabilitation projects, including the selection of materials and reinforcement techniques.
4. **Regulations and Legislation:**
* You will become familiar with current regulations and legislation regarding earthquake-resistant construction in different countries.
* You will learn to interpret and apply seismic codes and standards, such as structural design codes and seismic safety standards.
* You will understand the legal and regulatory aspects related to seismic risk assessment and mitigation.
5. **Seismic Risk Management:**
* You will acquire knowledge about seismic risk management, including emergency preparedness, disaster response, and post-earthquake recovery.
* You will learn to develop contingency plans and coordinate responses to seismic events.
* You will develop communication and collaboration skills to work in multidisciplinary teams and to interact with authorities, institutions, and the community.
2. **Structural Strengthening and Advanced Seismic Design**
-
You will master the analysis of structural response to complex phenomena such as flap-lag-torsion coupling, evaluating the stability and dynamic behavior of structures under specific loads.
- You will delve into the study of whirl flutter, a critical aerodynamic-elastic phenomenon that can cause catastrophic failures in rotating components, and learn to mitigate its effects through design and analysis techniques.
- You will understand fatigue failure mechanisms and apply analysis methods to predict the service life of structural components, ensuring long-term integrity and reliability.
- You will learn to dimension and optimize the design of laminates made from composite materials, using finite element (FE) methods to simulate their structural behavior under various loading conditions.
You will design and analyze advanced structural joints, including bonded joints, applying FE modeling techniques to evaluate their strength, stiffness, and durability.
You will apply the principles of damage tolerance, developing strategies to assess damage tolerance and crack propagation in structures, enabling proactive safety management.
You will implement non-destructive testing (NDT) techniques such as UT (ultrasound), RT (radiography), and thermography to inspect and evaluate the structural integrity of components without damaging them, thus optimizing maintenance and safety.
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. **Structural Rehabilitation, Damage Assessment, and Seismic Mitigation Strategies**
4. **Structural Rehabilitation, Damage Assessment, and Seismic Mitigation Strategies**
-
Identify and assess damage mechanisms in structures, including seismic vulnerability analysis.
-
Master advanced damage assessment techniques, such as non-destructive testing (NDT) and structural modeling.
-
Understand the principles of structural rehabilitation, including reinforcement and repair of damaged elements.
-
Design and implement seismic mitigation strategies, such as base isolation and damping.
-
Analyze the seismic behavior of different types of structures, including buildings and bridges.
-
Use specialized software for simulation and structural analysis in seismic contexts.
-
Study relevant international and local seismic design codes and standards.
Develop skills in managing seismic rehabilitation and mitigation projects.
Evaluate the effectiveness of seismic mitigation strategies through analysis and testing.
Understand the economic and social aspects of seismic rehabilitation and resilience.
5. **Innovative Strategies in Seismic Rehabilitation and Structural Vulnerability Analysis**
5. **Innovative Strategies in Seismic Rehabilitation and Structural Vulnerability Analysis**
- Identify and assess the seismic vulnerability of existing structures using advanced methods.
- Apply nonlinear structural analysis techniques to simulate the behavior of buildings under extreme seismic loads.
- Design and evaluate innovative seismic rehabilitation strategies, including the use of seismic isolators and dampers.
- Understand and apply current seismic design codes and regulations.
- Conduct case studies on the seismic rehabilitation of historical and modern buildings.
- Use specialized software for structural analysis and seismic rehabilitation design.
- Analyze different types of structural failures in a seismic context, including shear, flexural, and torsional collapse.
- Evaluate the efficiency and cost-benefit of The different seismic rehabilitation strategies.
Develop customized solutions for seismic rehabilitation, considering the specific characteristics of each structure.
Analyze the impact of seismic rehabilitation on the service life and performance of structures.
6. **Structural Design and Optimization for Seismic Rehabilitation of Buildings**
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 Seismic Rehabilitation and Vulnerability
- Civil engineers, architects, and construction professionals with a university degree.
- Professionals involved in the design, construction, supervision, and/or rehabilitation of structures.
- Public officials and technical staff from government institutions related to seismic risk management and urban planning.
- Consultants and advisors in structural safety and natural disaster management.
- 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 — Comprehensive Seismic Risk Assessment
1.1 Fundamentals of Seismology and Structural Geology
1.2 Identification and Characterization of Seismic Hazards
1.3 Seismic Hazard Assessment: Probabilistic and Deterministic Methods
1.4 Seismic Vulnerability: Concepts and Models
1.5 Seismic Risk Analysis: Approaches and Methodologies
1.6 Assessment of the Socioeconomic Impact of Earthquakes
1.7 Regulatory and Normative Framework for Seismic Risk Management
1.8 Seismic Microzonation and Site Response Studies
1.9 Application of Software in Seismic Risk Assessment
1.10 Case Studies: Risk Analysis in Different Types of Structures
Module 2 — Structural Strengthening and Advanced Seismic Design
2.1 Principles of Seismic-Resistant Design: Philosophy and Objectives
2.2 Seismic Design Standards and Codes: Eurocodes, ACI, etc.
2.3 Design of Reinforced Concrete Structures for Earthquakes: Details and Requirements
2.4 Design of Steel Structures for Earthquakes: Connections and Systems
2.5 Seismic Isolation Systems: Design and Applications
2.6 Energy Dissipation Systems: Design and Selection
2.7 Advanced Seismic Analysis Techniques: Dynamic and Nonlinear Analysis
2.8 Foundation Design in Seismic Zones
2.9 Seismic Modeling and Simulation with Specialized Software
2.10 Structural Reinforcement Design: Strategies and Techniques
Module 3 — Damage Analysis, Structural Reinforcement, and Seismic Vulnerability Reduction
3.1 Post-Earthquake Structural Damage Inspection and Assessment
3.2 Types of Structural Damage: Identification and Classification
3.3 Diagnosis of Structural Failures: Methods and Techniques
3.4 Selection of Structural Reinforcement Strategies
3.5 Reinforcement Techniques with Carbon Fiber and Other Composite Materials
3.6 Reinforcement with Concrete and Steel Jackets
3.7 Design of Interventions for Seismic Vulnerability Reduction
3.8 Evaluation of the Effectiveness of Reinforcement Interventions
3.9 Case Studies: Damage Analysis and Reinforcement Solutions in Buildings
3.10 Cost Estimation and Planning of Reinforcement Work
Module 4 — Structural Rehabilitation, Damage Assessment, and Seismic Mitigation Strategies
4.1 Regulatory Framework for Seismic Rehabilitation
4.2 Damage Assessment Methodologies: Visual Inspection, Non-Destructive Testing
4.3 Rehabilitation Techniques for Reinforced Concrete Structures
4.4 Rehabilitation Techniques for Steel Structures
4.5 Rehabilitation of Masonry Walls and Composite Structural Systems
4.6 Design of Seismic Mitigation Systems in Existing Buildings
4.7 Analysis and Modeling of Structures for Seismic Rehabilitation
4.8 Design Considerations for the Rehabilitation of Historic Buildings
4.9 Implementation of Seismic Rehabilitation Projects: Practical Aspects 4.10 Case Studies: Seismic Rehabilitation of Residential and Commercial Buildings
Module 5 — Innovative Strategies in Seismic Rehabilitation and Structural Vulnerability Analysis
5.1 Innovative Materials and Technologies in Seismic Rehabilitation
5.2 Advanced Seismic Isolation and Energy Dissipation Systems
5.3 Seismic Vulnerability Analysis: Advanced Methods and Modeling
5.4 Evaluation of the Seismic Performance of Existing Structures
5.5 Structural Reinforcement with Advanced Composite Materials
5.6 Seismic Rehabilitation of High-Rise and Complex Structures
5.7 Use of Advanced Simulation Software in Seismic Rehabilitation
5.8 Optimization of Seismic Rehabilitation Design 5.9 Sustainability and Environmental Aspects in Seismic Rehabilitation
5.10 Case Studies: Implementation of Innovative Strategies
Module 6 — Structural Design and Optimization for the Seismic Rehabilitation of Buildings
6.1 Conceptual Design and Selection of Rehabilitation Strategies
6.2 Detailed Structural Analysis of Existing Buildings
6.3 Optimization of Structural Reinforcement Design
6.4 Reinforcement Design with Reinforced Concrete
6.5 Reinforcement Design with Structural Steel
6.6 Reinforcement Design with Composite Materials
6.7 Design of Seismic Isolation and Energy Dissipation Systems
6.8 Integration of Construction and Safety Aspects in the Design
6.9 Modeling and Simulation for Design Optimization 6.10 Practical Cases of Design and Optimization in Seismic Rehabilitation
Module 7 — Seismic Rehabilitation of Buildings: Modeling, Analysis, and Structural Reinforcement Strategies
7.1 Structural Modeling for Seismic Rehabilitation
7.2 Static and Dynamic Analysis of Existing Buildings
7.3 Evaluation of the Seismic Performance of Structures
7.4 Structural Reinforcement Strategies: Selection and Design
7.5 Reinforcement with Reinforced Concrete Jackets
7.6 Reinforcement with Structural Steel Systems
7.7 Reinforcement with Fiber Reinforced Polymer (FRP) Composite Materials
7.8 Design of Connections and Construction Details
7.9 Verification and Validation of the Rehabilitation Design
7.10 Case Studies: Seismic Rehabilitation of Different Types of Buildings
Module 8 — Advanced Modeling, Performance Evaluation, and Seismic Structural Rehabilitation of Buildings
8.1 Advanced Modeling of Complex Structures
8.2 Nonlinear Analysis for Seismic Evaluation
8.3 Performance-Based Seismic Performance Evaluation
8.4 Acceptance Criteria and Performance Levels
8.5 Structural Reinforcement Design with Advanced Techniques
8.6 Reinforcement with Innovative Materials and Cutting-Edge Technologies
8.7 Building Rehabilitation with Sustainable Technologies
8.8 Application of Specialized Software for Modeling and Analysis
8.9 Seismic Rehabilitation Project Management
8.10 Case Studies: Modeling, Analysis, and Rehabilitation in Real-World Projects
2. 2 Principles of Seismic Design: Philosophies and Standards
3. 2 Seismic Loads: Determination and Application in Structural Design
4. 3 Structural Analysis for Seismic Design: Static and Dynamic Methods
5. 4 Design of Structural Elements: Beams, Columns, and Walls
6. 5 Design of Seismic-Resistant Connections: Welds, Bolts, and Details
7. 6 Structural Strengthening: Techniques and Materials
8. 7 Design of Foundations for Seismic Resistance: Soil-Structure Interaction
9. 8 Design of Seismic Isolation and Energy Dissipation Systems
20. 9 Structural Modeling and Simulation for Seismic Design
22. 20 Case Studies: Seismic Design and Structural Strengthening in Real Buildings
3.3 Identification and classification of post-earthquake structural damage
3.2 Non-destructive testing (NDT) techniques
3.3 Evaluation of remaining capacity and structural deterioration
3.4 Traditional and advanced structural reinforcement methods
3.5 Design of reinforcements with fiber-reinforced polymer (FRP) materials
3.6 Reinforcement of reinforced concrete elements (columns, beams, slabs)
3.7 Reinforcement of masonry structures
3.8 Connection strategies and compatibility of reinforcements
3.9 Analysis of the effectiveness of implemented reinforcements
3.30 Documentation and quality control in reinforcement work
4.4 Diagnosis and assessment of damage to existing structures.
4.2 Seismic vulnerability assessment techniques.
4.3 Selection of seismic mitigation strategies.
4.4 Structural reinforcement design: walls, columns, and beams.
4.5 Use of reinforcement materials and technologies.
4.6 Structural analysis for seismic rehabilitation.
4.7 Modeling of damaged structural elements.
4.8 Reinforcement with carbon fiber and other technologies.
4.9 Implementation of seismic isolation strategies.
4.40 Case studies and effectiveness analysis.
5.5 Fundamentals of Seismic Risk: Key Concepts and Terminology
5.5 Identification and Assessment of Seismic Hazards: Seismic Sources, Hazard Maps, and Hazard Models
5.3 Seismic Vulnerability of Buildings: Types of Structures and Their Behavior During Earthquakes
5.4 Seismic Risk Assessment Methodologies: Probabilistic and Deterministic Analysis
5.5 Seismic Instrumentation and Structural Monitoring: Sensors, Data Acquisition Systems, and Analysis of Seismic Records
5.6 Seismic Risk Mitigation Techniques: Structural and Non-structural Measures
5.7 Case Studies: Application of Seismic Risk Assessment and Mitigation in Different Contexts
5.8 Regulatory Framework: Building Codes and Standards Related to Seismicity
5.9 Tools and Software for Seismic Risk Assessment 5.50 Seismic Risk Management: Emergency, Response, and Recovery Plans in Disaster Situations.
5.5 Principles of Seismic-Resistant Design: Philosophy, Objectives, and Design Criteria.
5.5 Seismic Design According to Regulations: International Codes and Standards.
5.3 Earthquake-Resistant Structural Systems: Design of Reinforced Concrete, Steel, and Masonry Structures.
5.4 Performance-Based Design: Concepts, Methodologies, and Applications.
5.5 Dynamic Structural Analysis: Modal Spectral Analysis and Time-History Analysis Methods.
5.6 Design of Foundations for Seismics: Seismic Considerations in the Design of Shallow and Deep Foundations.
5.7 Design of Non-Structural Elements: Partition Systems, Facades, and Other Elements.
5.8 Structural Strengthening Techniques: Reinforcement with Carbon Fiber, Steel, and Other Technologies. 5.9 Design of structures with seismic isolation and energy dissipation.
5.50 Case studies: Application of seismic design in real-world projects.
3.5 Inspection and evaluation of structural damage: Methodologies, tools, and protocols.
3.5 Types of seismic damage in structures: Cracks, deformations, collapses.
3.3 Damage analysis: Techniques for evaluating the severity and extent of damage.
3.4 Structural diagnosis: Identification of the causes of damage and their impact on safety.
3.5 Structural reinforcement strategies: Selection of the most appropriate reinforcement technique.
3.6 Carbon fiber reinforcement techniques: Applications and design.
3.7 Steel reinforcement: Reinforcement techniques using plates, profiles, and jackets.
3.8 Masonry reinforcement: Techniques for reinforcing and rehabilitating masonry walls. 3.9 Reducing Seismic Vulnerability: Mitigation Measures and Improvement of Seismic Performance
3.50 Case Studies: Damage Analysis and Reinforcement Strategies in Buildings Damaged by Earthquakes
4.5 Introduction to Structural Rehabilitation: Objectives and Scope
4.5 Damage Assessment and Structural Diagnosis for Rehabilitation
4.3 Seismic Evaluation Methodologies for Existing Buildings
4.4 Structural Reinforcement Techniques: Selection and Design
4.5 Reinforcing Reinforced Concrete Structures: Jacketing, Addition of Structural Elements, etc.
4.6 Rehabilitation of Steel Structures: Reinforcement of Beams, Columns, and Connections
4.7 Rehabilitation of Masonry Structures: Reinforcement of Walls and Vaults
4.8 Seismic Mitigation Strategies: Seismic Isolation and Energy Dissipation in Existing Buildings 4.9 Regulatory and Legal Aspects of Seismic Rehabilitation
4.50 Case Studies: Rehabilitation of Historic and Modern Buildings
5.5 Introduction to Innovative Strategies in Seismic Rehabilitation
5.5 High-Performance Composite Materials in Rehabilitation
5.3 Next-Generation Seismic Isolation and Energy Dissipation Systems
5.4 Pre-Tensioning and Post-Tensioning Techniques in Rehabilitation
5.5 Seismic Rehabilitation with BIM (Building Information Modeling) Technologies
5.6 Advanced Structural Vulnerability Analysis: Nonlinear Methods and Fragility Analysis
5.7 Performance-Based Design in Rehabilitation
5.8 Integration of Smart Technologies in Seismic Rehabilitation
5.9 Case Studies: Application of Innovative Strategies in Real-World Projects
5.50 Future Trends in Seismic Rehabilitation
6.5 Fundamentals of Structural Design for Seismic Rehabilitation
6.5 Design Criteria and Applicable Regulations
6.3 Structural Modeling for Seismic Rehabilitation
6.4 Static and Dynamic Structural Analysis
6.5 Design of Structural Reinforcement Elements: Beams, Columns, Walls
6.6 Design of Connections and Joints in Rehabilitated Structures
6.7 Structural Optimization: Design of Efficient Sections and Reinforcements
6.8 Design of Seismic Isolation and Energy Dissipation Systems
6.9 Durability and Service Life Considerations for Rehabilitated Structures
6.50 Case Studies: Structural Design and Optimization in Seismic Rehabilitation Projects
7.5 Advanced Structural Modeling for Seismic Rehabilitation: Tools and Software
7.5 Nonlinear Seismic Analysis: Nonlinear Static (Pushover) and Nonlinear Dynamic Analysis 7.3 Seismic Performance Assessment of Existing Structures
7.4 Structural Reinforcement Strategies: Selection and Design of Reinforcements
7.5 Reinforcement of Reinforced Concrete Structures: Techniques and Applications
7.6 Reinforcement of Steel Structures: Techniques and Applications
7.7 Rehabilitation of Masonry Structures: Techniques and Applications
7.8 Design of Seismic Isolation and Energy Dissipation Systems
7.9 Implementation of Reinforcement Strategies
7.50 Case Studies: Modeling, Analysis, and Reinforcement in Seismic Rehabilitation Projects
8.5 Advanced Structural Modeling: Three-Dimensional Models, Finite Elements, and Specialized Software
8.5 Nonlinear Seismic Analysis: Nonlinear Static (Pushover) and Nonlinear Dynamic Analysis
8.3 Seismic Performance Assessment: Acceptance Criteria and Performance Levels 8.4 Design of seismic rehabilitation strategies: Selection of reinforcement, isolation, and energy dissipation techniques.
8.5 Reinforcement with carbon fiber and other composite materials.
8.6 Design of seismic isolation systems.
8.7 Design of energy dissipation systems.
8.8 Implementation of rehabilitation strategies.
8.9 Verification and validation of the model.
8.50 Case studies: Advanced modeling, analysis, and seismic rehabilitation of buildings of different typologies.
6.6 Principles of Seismic Design for Structural Rehabilitation
6.2 Applicable Seismic Design Codes and Standards
6.3 Structural Reinforcement Strategies: Methods and Materials
6.4 Design of Structural Interventions: Foundations and Superstructures
6.5 Structural Modeling for Seismic Analysis
6.6 Evaluation of Existing Seismic Capacity
6.7 Design of Construction Details for Seismic Rehabilitation
6.8 Design Optimization: Cost, Time, and Performance
6.9 Seismic Design of Non-Structural Elements
6.60 Case Studies: Real-World Applications and Lessons Learned
7.7 Fundamentals of Seismology and Plate Tectonics
7.2 Identification and Characterization of Seismic Hazards
7.3 Assessment of Local and Regional Seismic Hazard
7.4 Seismic Risk Assessment Methodologies
7.7 Seismic Vulnerability Analysis of Structures
7.6 Seismic Risk Mitigation Strategies
7.7 Design of Seismic Risk Maps
7.8 Implementation of Earthquake Response Plans
7.9 Case Studies of Assessment and Mitigation
7.70 Standards and Regulations for Seismic Risk Assessment
2.7 Principles of Earthquake-Resistant Design
2.2 Design of Earthquake-Resistant Structural Systems
2.3 Design of Foundations in Seismic Zones
2.4 Design of Shear Walls and Moment-Resisting Frames
2.7 Design of seismic isolation systems.
2.6 Design of seismic damping systems.
2.7 Design of structures with energy dissipation.
2.8 Application of advanced structural analysis software.
2.9 Seismic design according to international standards.
2.70 Practical cases of seismic design.
3.7 Methodologies for inspection and evaluation of seismic damage.
3.2 Classification of damage and its severity.
3.3 Structural analysis of damaged structures.
3.4 Structural reinforcement techniques for concrete elements.
3.7 Structural reinforcement techniques for steel elements.
3.6 Reinforcement of walls and diaphragms.
3.7 Reinforcement of foundations.
3.8 Selection of reinforcement materials and techniques.
3.9 Design of structural reinforcement interventions. 3.70 Damage Analysis and Reinforcement Case Studies
4.7 Diagnosis and Evaluation of Existing Buildings
4.2 Design of Seismic Rehabilitation Strategies
4.3 Structural Reinforcement with Traditional Techniques
4.4 Structural Reinforcement with Innovative Techniques
4.7 Rehabilitation of Non-Structural Systems
4.6 Implementation of Vibration Control Systems
4.7 Durability and Sustainability Considerations
4.8 Seismic Rehabilitation Project Management
4.9 Legal and Regulatory Aspects of Rehabilitation
4.70 Successful Rehabilitation Case Studies
7.7 Advanced Technologies for Seismic Rehabilitation
7.2 Composite Materials in Structural Rehabilitation
7.3 Seismic-Resistant Design with FRP and CFRP
7.4 Advanced Seismic Vulnerability Analysis
7.7 Seismic Behavior Modeling and Simulation 7.6 Reinforcement with Seismic Isolation Systems
7.7 Rehabilitation of Historic Buildings
7.8 Design of Non-Structural Mitigation Strategies
7.9 Cost-Benefit Analysis in Seismic Rehabilitation
7.70 Future Trends in Structural Rehabilitation
6.7 Optimization of Structural Design for Rehabilitation
6.2 Performance-Based Design
6.3 Selection of Innovative Materials and Technologies
6.4 Design of Energy Dissipation Systems
6.7 Advanced Modeling and Simulation
6.6 Sensitivity Analysis and Optimization
6.7 Design of Construction Details and Connections
6.8 Safety and Constructability Considerations
6.9 Case Studies of Optimized Design
6.70 Standards and Regulations in Seismic Design
7.7 Advanced Structural Modeling with Specialized Software
7.2 Model Calibration and Sensitivity Analysis
7.3 Seismic Performance Assessment
7.4 Reinforcement Strategies Using Traditional Techniques
7.7 Reinforcement Strategies Using Innovative Techniques
7.6 Design of Vibration Control Systems
7.7 Risk Analysis and Rehabilitation Planning
7.8 Durability and Maintenance Considerations
7.9 Rehabilitation Case Studies
7.70 Rehabilitation Implementation and Monitoring
8.7 Advanced Modeling with Analysis Software
8.2 Structural Vulnerability Assessment
8.3 Nonlinear Dynamic Analysis
8.4 Design of Rehabilitation Interventions
8.7 Seismic Isolation and Damping Systems
8.6 Reinforcement with Composite Materials
8.7 Design and Analysis of Construction Details
8.8 Post-Rehabilitation Performance Assessment
8.9 Seismic Rehabilitation Case Studies 8.70 Sustainability and resilience aspects.
8.8 Advanced Seismic Structural Modeling: Methodologies and Software
8.8 Nonlinear Dynamic Analysis: Implementation and Applications
8.3 Seismic Performance Evaluation: Criteria and Levels
8.4 Structural Reinforcement Strategies: Materials and Techniques
8.5 Intervention Design: Reinforcement of Critical Elements
8.6 Seismic Rehabilitation: Design and Detailing of Connections
8.7 Damage Modeling and Analysis: Seismic Scenarios
8.8 Case Studies: Seismic Rehabilitation of Buildings
8.8 Rehabilitation Optimization: Cost-Benefit and Efficiency
8.80 Post-Rehabilitation Inspection and Monitoring: Performance Verification
9.9 Introduction to Seismology and Geotechnical Engineering
9.9 Identification and Assessment of Seismic Hazards
9.3 Analysis of the Seismic Vulnerability of Existing Buildings
9.4 Seismic Risk Assessment Methods
9.5 Seismic Risk Mitigation Strategies
9.6 Current Regulations and Legislation
9.7 Case Studies and Practical Examples
9.8 Development of Seismic Risk Management Plans
9.9 Implementation and Monitoring of Mitigation Measures
9.90 Simulation and Analysis of Seismic Scenarios
9.9 Principles of Earthquake-Resistant Design
9.9 Seismic Design Standards and Codes
9.3 Selection of Materials and Structural Systems
9.4 Foundation Design in Seismic Zones 9.5 Design of structural elements: beams, columns, walls.
9.6 Design of seismic-resistant connections and joints.
9.7 Design of seismic damping and isolation systems.
9.8 Structural dynamic analysis and design spectra.
9.9 Advanced structural modeling and simulation.
9.90 Structural optimization and performance-based design.
3.9 Inspection and evaluation of post-earthquake structural damage.
3.9 Types of damage and failure mechanisms in buildings.
3.3 Damage analysis techniques: visual, non-destructive.
3.4 Diagnosis of structural vulnerability.
3.5 Selection of structural reinforcement techniques.
3.6 Reinforcement of reinforced concrete structural elements.
3.7 Reinforcement of steel structures.
3.8 Reinforcement of masonry and composite structures. 3.9 Cost-benefit analysis of reinforcement options.
3.90 Preparation of technical reports for damage analysis and reinforcement.
4.9 Principles of structural rehabilitation.
4.9 Evaluation of the existing structural condition.
4.3 Damage and pathology assessment techniques.
4.4 Rehabilitation strategies: reinforcement, replacement, demolition.
4.5 Reinforcement of reinforced concrete structures: jacketing, grouting.
4.6 Reinforcement of steel structures: welding, bolts, plates.
4.7 Rehabilitation of masonry structures.
4.8 Design and execution of structural interventions.
4.9 Regulatory and legal aspects of rehabilitation.
4.90 Case studies and best practices in rehabilitation.
5.9 Innovative technologies in seismic rehabilitation.
5.9 Seismic isolation systems: foundations, dampers. 5.3 Vibration control systems: mass, fluid.
5.4 Composite materials in structural rehabilitation.
5.5 Reinforcement with carbon and glass fibers.
5.6 Advanced seismic vulnerability analysis.
5.7 Modeling and simulation of complex structures.
5.8 Goal-based seismic performance analysis.
5.9 Design of optimized rehabilitation solutions.
5.90 Integration of innovative technologies in real-world projects.
6.9 Structural design for seismic rehabilitation.
6.9 Performance-based design criteria.
6.3 Selection of structural systems and materials.
6.4 Optimization of structural design.
6.5 Design of reinforcement: beams, columns, walls.
6.6 Design of reinforced connections and joints.
6.7 Design of seismic protection systems.
6.8 Advanced structural modeling and analysis. 6.9 Design Verification and Quality Control
6.90 Practical Cases of Structural Design and Optimization
7.9 Modeling of Existing and Damaged Structures
7.9 Structural Analysis and Modeling Software
7.3 Modeling of Structural Elements: Beams, Columns, Walls
7.4 Modeling of Foundations and Soil-Structures
7.5 Seismic Analysis: Static, Dynamic, Nonlinear
7.6 Evaluation of Seismic Performance
7.7 Structural Reinforcement Strategies
7.8 Design of Seismic Reinforcements: Techniques and Materials
7.9 Modeling and Analysis of Reinforced Behavior
7.90 Case Studies and Application Examples
8.9 Advanced Structural Modeling with Specialized Software
8.9 Modal and Spectral Response Analysis
8.3 Time-History and Nonlinear Analysis 8.4 Advanced Seismic Performance Evaluation
8.5 Performance-Based Design Criteria
8.6 Advanced Structural Reinforcement Strategies
8.7 Reinforcement with Composite Materials and Isolation Systems
8.8 Modeling the Behavior of Reinforced Structures
8.9 Seismic Risk and Vulnerability Assessment
8.90 Case Studies and Practical Applications in Seismic Rehabilitation
1.1 Definition of the scope and objectives of the seismic rehabilitation project
1.2 Collection and analysis of pre-existing information: plans, geotechnical studies, etc.
1.3 Assessment of the building’s initial seismic vulnerability
1.4 Conceptual design of structural rehabilitation solutions
1.5 Selection of materials and construction technologies
1.6 Structural modeling and advanced seismic analysis
1.7 Detailed design of reinforcement and repair elements
1.8 Planning of work execution and schedule
1.9 Cost estimation and detailed budget
1.10 Presentation and defense of the final project
- 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.