Diploma in Applied Biomechanics and Exos Selection
Sobre nuestro Diploma in Applied Biomechanics and Exos Selection
The Diploma in Applied Biomechanics and Exoskeleton Selection delves into the study of human movement, muscle strength, and the body’s interaction with the environment, integrating knowledge of biomechanics, physiology, and engineering. It focuses on the application of biomechanical principles to the analysis and design of exoskeletons, evaluating their impact on rehabilitation, functional assistance, and athletic performance. It includes the analysis of the kinematics and dynamics of movement, the design and selection of exoskeletons, with special emphasis on ergonomics and the human-machine interface. The program provides knowledge of biomechanical measurement techniques, the use of simulation and analysis software, and the evaluation of the effectiveness and safety of exoskeletons. Participants will acquire skills to assess user needs, select the appropriate exoskeleton, and optimize its performance. They prepare for professional roles in areas such as rehabilitation, biomedical engineering, the sports industry, and research, contributing to the development of innovative solutions to improve quality of life and human performance. Target keywords (natural occurrences in the text): biomechanics, exoskeletons, human movement, rehabilitation, biomedical engineering, muscle strength, ergonomics, diploma in biomechanics.
Diploma in Applied Biomechanics and Exos Selection
- Modalidad: Online
- Duración: 8 meses
- Horas: 900 H
- Idioma: ES / EN
- Créditos: 60 ECTS
- Fecha de matrÃcula: 19-06-2026
- Fecha de inicio: 30-07-2026
- Plazas disponibles: 3
1.699 $
Competencias y resultados
Qué aprenderás
1. Applied Biomechanics and Exos Selection: An In-Depth Diploma Course
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Understand the fundamentals of human biomechanics and its application in the design and selection of exoskeletons.
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Evaluate the biomechanical needs of diverse users and environments for the adaptation of exoskeletons.
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Analyze the design principles of exoskeletons, including considerations regarding joints, actuators, and sensors.
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Study the key materials and technologies in the manufacture of exoskeletons, such as polymers, metals, and control systems.
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Evaluate the efficiency and safety of exoskeletons in different applications, including rehabilitation and work assistance.
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Design and simulate exoskeletons using specialized software, considering aspects such as kinematics, dynamics, and biomechanics.
Understand the relevant regulations and standards for the design and use of exoskeletons, including certification and ethics.
Analyze case studies of successful exoskeletons in different areas, such as medicine, industry, and sports.
Identify opportunities for research and development in the field of biomechanics and exoskeletons.
Apply the acquired knowledge to the selection, adaptation, and evaluation of exoskeletons in real-world situations.
2. Biomechanical Analysis, Exos Design, and Optimization of Human Performance
- Understand the principles of human biomechanics and their application in movement analysis.
- Evaluate and diagnose joint forces and moments, pressures, and muscle imbalances.
- Design and develop exoskeletons (exos) to improve human mobility, strength, and endurance.
- Explore different types of exos: passive, active, and hybrid, and their applications in various fields.
- Optimize human performance through biomechanical and ergonomic strategies.
- Apply training and rehabilitation principles based on biomechanical analysis.
- Use biomechanical simulation and analysis software to evaluate movement and performance.
- Integrate biomechanics with other disciplines such as physiology and psychology. sport.
- Research the latest trends and advances in biomechanics, exoskeleton design, and performance optimization.
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. Mastery of Biomechanics, Selection of Exos, and Enhancement of Human Movement [...]
4. Biomechanics Mastery, Exoskeleton Selection, and Human Movement Enhancement
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Fundamentals of Human Biomechanics: Understanding the body’s forces and movements.
- Analysis of Kinetics and Kinematics: Studying movements and the forces involved.
- Biomechanics of the Locomotor System: In-depth study of muscles, bones, and joints.
- Design and Evaluation of Exoskeletons: Principles for designing, evaluating, and selecting exoskeletons.
- Engineering Principles for Exoskeletons: Materials, actuators, and sensors for exoskeletons.
- Control and Adaptation of Exoskeletons: Control and adaptation systems for different tasks.
- Applications in Rehabilitation and Enhancement: Use of exoskeletons in medicine and performance.
- Selection of Specific Exoskeletons: Selection criteria based on individual needs.
- Testing and Validation of Exoskeletons: Testing methods to validate performance and safety.
- Ethics and Legal Aspects: Ethical and legal considerations in the use of exoskeletons.
5. Exos Biomechanics: Selection, Application, and Optimization of Movement
5. Exoskeleton Biomechanics: Selection, Application, and Movement Optimization
- Understand the fundamental principles of biomechanics applied to exoskeleton systems.
- Evaluate the body-exoskeleton interaction, considering load transfer and physiological adaptation.
- Identify and analyze the key variables for selecting the appropriate exoskeleton for each need, including performance, safety, and comfort criteria.
- Explore different exoskeleton technologies (passive, active, hybrid) and their respective applications in rehabilitation, work assistance, and capacity augmentation.
- Study the kinematics and kinetics of human movement, focusing on optimizing the design and control of exoskeletons.
- Understand the methods for the Optimization of exoskeleton-assisted movement, including calibration, customization, and programming.
- Analyze the effects of the exoskeleton on biomechanical efficiency and energy expenditure during various tasks.
- Evaluate the safety and risks associated with the use of exoskeletons, including injury prevention and fatigue management.
- Use simulation and modeling tools to predict the behavior of exoskeletons and optimize their design.
- Apply user-centered design strategies to ensure the usability and acceptance of exoskeletons.
6. Biomechanics and Exos: Design, Selection, and Optimization of Human Movement [The following appears to be unrelated and possibly machine-translated gibberish:] ...
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 Applied Biomechanics and Exos Selection
- 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 — Introduction to Biomechanics and Exos
1.1 Fundamentals of Biomechanics: Principles and Key Concepts
1.2 Introduction to Exos: Types and Classifications
1.3 Applications of Biomechanics in Exo Design
1.4 Analysis of Human Movement: Kinematics and Kinetics
1.5 Coordinate Systems and Vector Analysis
1.6 Basic Exo Design: Mechanical Considerations
1.7 Materials and Technologies in Exo Manufacturing
1.8 Human-Exo Interaction: Interface and Control
1.9 Ethics and Safety in Exo Use
1.10 Current and Future Landscape of Biomechanics and Exos
1.10
2.2 Fundamentals of Biomechanics: Principles and Key Concepts.
2.2 Introduction to Exos: Types, Classification, and Applications.
2.3 Biological Systems: Structure and Function of the Human Body.
2.4 Biomechanics and Movement Patterns: Fundamental Analysis.
2.5 Human-Exo Interaction: Design and Initial Considerations.
2.6 Legal Framework: Standards and Regulations for Exos.
2.7 Materials and Components of Exos.
2.8 Introduction to Biomechanical Engineering.
2.9 Ethics and Safety in the Use of Exos.
2.20 Case Study: Analysis of Existing Examples of Exos.
2.2 Movement Analysis Methods: Kinetics and Kinematics.
2.2 Human Gait Assessment: Analysis and Diagnosis.
2.3 3D Movement Analysis: Software and Tools. 2.4 Force and Moment Analysis: Fundamentals and Applications.
2.5 Musculoskeletal Dynamics: Modeling and Simulation.
2.6 Sports Biomechanics: Performance Analysis and Optimization.
2.7 Clinical Biomechanics: Injury Assessment and Treatment.
2.8 Biomechanical Data Collection and Processing.
2.9 Data Analysis: Statistical Methods and Visualization.
2.20 Case Study: Analysis of Specific Movements.
3.2 Exos Design: Principles and Considerations.
3.2 Exos Selection: Criteria and Methodology.
3.3 Component Design: Exos Design and its Elements.
3.4 Modeling and Simulation in Exos Design.
3.5 Exos Fabrication and Prototyping. 3.6 Ergonomic Design: Adapting to User Needs.
3.7 Control Design: Exos Control Systems.
3.8 Testing and Validation: Exos Trials and Evaluation.
3.9 Cost and Feasibility Considerations in Design.
3.20 Case Study: Analysis of Specific Exos Designs.
4.2 Performance Optimization: Principles and Strategies.
4.2 Biomechanics and Sports Training.
4.3 Adapting and Customizing Exos for Performance.
4.4 Integrating Exos into Training Programs.
4.5 Performance Monitoring with Exos.
4.6 Biomechanical Feedback for Optimization.
4.7 Designing Exos-Assisted Exercises.
4.8 Recovery and Rehabilitation with Exos.
4.9 Long-Term Performance Improvement Strategies.
4.20 Case Study: Performance Optimization in Specific Sports
5.2 Applications in Rehabilitation: Exos and Physiotherapy
5.2 Exos in the Workplace: Ergonomics and Injury Prevention
5.3 Applications in the Military Sector: Exos for the Force
5.4 Exos in Industry: Applications and Automation
5.5 Exos in Healthcare: Mobility and Care
5.6 Exos and the Elderly: Mobility and Quality of Life
5.7 Design of Exos for Children and Adolescents
5.8 Applications in Space and Extreme Environments
5.9 Ethical and Social Considerations of the Applications
5.20 Case Study: Analysis of Specific Applications
6.2 Biomechanics and Implementation Strategies: Overview 6.2 Exo Selection: Key Factors for Choice
6.3 Designing Exo Implementation Programs
6.4 Integration with Existing Technologies
6.5 Staff Training and Development
6.6 Legal and Regulatory Aspects of Implementation
6.7 Evaluating Results and Success Metrics
6.8 Exo Maintenance and Sustainability
6.9 Communication and Dissemination Strategies
6.20 Case Study: Implementing Exos in a Specific Environment
3.3 Fundamental Principles of Biomechanics
3.2 Biomechanical Assessment: Methods and Tools
3.3 Kinematics and Kinetics of Human Movement
3.4 Biomechanical Data Analysis
3.5 Introduction to Exos: Types and Functions
3.6 Exo Selection: Criteria and Considerations
3.7 Exo Compatibility and Adaptation
3.8 Exo Design and Customization
3.9 Biomechanical and Exo Integration
3.30 Case Studies and Practical Applications
Module 4 — Biomechanical Analysis and Exos Design
4.4 Principles of Biomechanics: Forces, Moments, and Analysis of Human Movement
4.2 Kinematics and Kinetics: Measurement and Analysis of Movement
4.3 Biomechanical Modeling: Simplification and Simulation of the Human Body
4.4 Exos Design: Principles, Types, and Key Considerations
4.5 Exos Selection: Criteria, Evaluation, and Adaptation
4.6 Design and Analysis of Exos Components
4.7 Human-Machine Interfaces: Interaction and Control
4.8 Biomechanical Optimization: Movement Performance and Efficiency
4.9 Evaluating the Impact of Exos on Health and Performance
4.40 Case Studies: Practical Applications and Success Stories
5. Applied Biomechanics and Exos Selection: An In-Depth Diploma
5.5 Introduction to Biomechanics: Fundamental Concepts and Their Application
5.5 Principles of Biomechanics in Human Movement
5.3 Conceptual Framework of Biomechanics for Exos Selection
5.4 Types of Exos: Classification and Characteristics
5.5 Biomechanical Assessment Tools: Methods and Techniques
5. Biomechanical Analysis, Exos Design, and Optimization of Human Performance
5.5 Movement Analysis: Techniques and Applications
5.5 Exos Design: Ergonomic and Biomechanical Considerations
5.3 Selection of Components and Materials for Exos
5.4 Optimization of Human Performance Through Exos
5.5 Case Studies: Exos in Different Contexts
3. Advanced Biomechanical Exploration, Exos Selection, and Specialized Applications
3.5 Advanced Biomechanics: Models and Simulations
3.5 Exos Selection: Evaluation and Comparison Criteria
3.3 Specialized Applications: Rehabilitation, Sports, Industry
3.4 Exos in Work Environments: Risk and Benefit Analysis
3.5 Integration of Exos with Other Technologies
4. Biomechanical Mastery, Exos Selection, and Human Movement Enhancement
4.5 Biomechanical Fundamentals: Review and Update
4.5 Strategic Exos Selection: Methodology and Best Practices
4.3 Human Movement Enhancement: Training Program Design
4.4 Performance Evaluation and Monitoring with Exos
4.5 Ethical and Regulatory Aspects of Exos
5. Biomechanics and Exos: Selection, Application, and Optimization of Movement
5.5 Selection of exos: criteria and key factors.
5.5 Application of exos in various disciplines.
5.3 Movement optimization: strategies and tools.
5.4 Design and development of control systems for exos.
5.5 Impact of exos on health and well-being.
6. Biomechanics and Exos: Design, Selection, and Optimization of Human Movement
6.5 Design of exos: principles and engineering considerations.
6.5 Selection of exos: needs assessment and objectives.
6.3 Optimization of human movement: biomechanics and training.
6.4 Integration of sensors and feedback systems.
6.5 Research and development in the field of exos.
7. Biomechanics Applied to Exos: Selection, Analysis, and Optimization of Human Movement
7.5 Applied Biomechanics: Fundamentals and Applications
7.5 Biomechanical Analysis: Techniques and Tools
7.3 Exo Selection: Evaluation and Decision Criteria
7.4 Movement Optimization: Strategies and Techniques
7.5 Implementation and Evaluation of Exo Programs
8. Applied Biomechanics and Exo Selection: Analysis, Design, and Strategic Implementation
8.5 Biomechanical Analysis: Methodologies and Tools
8.5 Exo Design: Principles and Engineering Considerations
8.3 Strategic Implementation: Selection and Use of Exos
8.4 Evaluation of the Effectiveness and Safety of Exos
8.5 Future Trends and Opportunities in the Field of Exos
6.6 Introduction to Biomechanics and Fundamentals of Human Movement
6.2 Design Principles of Exos: Types, Mechanisms, and Materials
6.3 Biomechanical Analysis: Movement and Load Assessment
6.4 Exos Selection: Criteria, Evaluation, and Adaptation
6.5 Optimizing Human Movement with Exos: Strategies and Techniques
6.6 Specialized Applications: Rehabilitation, Ergonomics, and Sports Performance
6.7 Design and Construction of Exos Prototypes
6.8 Evaluation and Validation of Exos: Tests and Methodologies
6.9 Regulatory and Ethical Aspects of Exos Use
6.60 The Future of Biomechanics and Exos Technology
**Module 7 — Introduction to Biomechanics and Exos**
7. 7 Basic Concepts of Biomechanics: Definition, scope, and applications.
2. 2 Fundamental principles of biomechanics: Kinematics and kinetics.
3. 3 Introduction to exos: Definition, types, and classification.
4. 4 History and evolution of exos: From science fiction to reality.
7. 7 Key components of exos: Actuators, sensors, and control systems.
6. 6 Biomechanics and human movement: Analysis of patterns and forces.
7. 7 Human-exo interaction: Key biomechanical principles.
8. 8 Current legislation and regulations: Ethical considerations.
9. 9 The future of biomechanics and exos: Trends and projections.
70. 70 Case studies: Initial applications of exos.
**Module 2 — Principles of Biomechanics and Exoskeleton Selection**
2.7 Biomechanics of Human Movement: Analysis of Joints and Segments.
3.2 Principles of Fluid Mechanics: Application to Exoskeleton Design.
4.3 Exoskeleton Selection: Evaluation Criteria.
7.4 Exoskeleton Design: Material Properties.
6.7 Gait and Other Movement Analysis: Methods and Tools.
7.6 Biomechanics of Posture and Balance: Analysis and Applications.
8.7 Biomechanical Factors in Exoskeleton Selection: Age, Weight, and Physical Condition.
9.8 Exoskeleton Selection Based on Pathology: Strategies and Considerations.
70.9 Ergonomic Design of Exoskeletons: Adaptation to User Needs.
77.70 Case Studies: Exoskeleton Selection for Different Applications.
**Module 3 — Biomechanical Analysis and Exoskeleton Design**
3.7 Biomechanical Analysis Techniques: Kinematic and Kinetic Methods
4.2 Exoskeleton Design: Modeling and Simulation
7.3 Biomechanical Data Acquisition and Processing Systems
6.4 Materials and Manufacturing Technologies for Exoskeletons
7.7 Biomechanics of the Human-Exoskeleton Interface: Design and Optimization
8.6 Design of Control Systems for Exoskeletons: Strategies and Algorithms
9.7 Design of Control Systems for Exoskeletons: Software and Programming
70.8 Exoskeleton Design: Safety and Certification Aspects
77.9 Failure Analysis and Safety Measures
72.70 Design Projects: Exoskeleton Development
**Module 4 — Optimizing Human Performance**
4.7 The impact of exos on physical performance: Strength, endurance, and speed.
7.2 Training with exos: Conditioning and rehabilitation programs.
6.3 Biomechanical analysis of sports movement: Optimizing techniques.
7.4 Physiological adaptations to the use of exos: Short- and long-term effects.
8.7 Designing exos for specific sports: Biomechanical considerations.
9.6 Recovery and injury prevention strategies: Using exos.
70.7 Psychosocial factors in human performance: Motivation and adherence.
77.8 Designing exos for cognitive enhancement: Applications and challenges.
72.9 Optimizing performance in work environments: exos and productivity.
73.70 Case studies: Applications of exos in sports and work.
**Module 7 — Specialized Applications and Strategies**
7. Exos Applications in Rehabilitation: Program Design and Strategies
6. Exos in Work Environments: Design, Implementation, and Evaluation
7. Exos Design for Military Personnel: Applications and Challenges
8. Exos and Assisted Mobility: Design and Adaptation Strategies
9. Exos Implementation Strategies: Needs Assessment and Selection
70. Feasibility Analysis: Cost-Benefit and Return on Investment
77. Marketing and Sales Strategies for Exos
72. Legislation and Regulation: Implications for the Exos Industry
73. The Future of Exos: Challenges and Opportunities
74. Final Project Presentations: Exos Design and Implementation Plans
8.8 Needs Assessment and Goal Setting
8.8 Exos Selection: Criteria and Methodology
8.3 Exos Design and Engineering: Principles and Considerations
8.4 Exos Implementation: Integration and Adaptation
8.5 Data Analysis and Performance Evaluation
8.6 Optimizing Human Movement with Exos
8.7 Safety Protocols and Ethical Considerations
8.8 Case Studies: Practical Applications and Results
8.8 Exos Project Planning and Management
8.80 Future Trends and Advances in Biomechanics and Exos
9.9 Fundamentals of Biomechanics: Principles and applications in human movement.
9.9 Introduction to Exos: Types, functions, and classification.
9.3 Anatomy and Physiology of Movement: Foundations for biomechanical analysis.
9.4 Biomechanics of Movement: Kinematics and kinetics.
9.5 Principles of Exo Design: Ergonomic and safety considerations.
9.6 Materials and Technologies in Exos: Selection and applications.
9.7 Biomechanical Evaluation Methodologies: Instrumentation and analysis.
9.8 Introduction to Exo Selection: Criteria and considerations.
9.9 Ethics and Legal Considerations in the use of Exos.
9.90 Future Trends in Biomechanics and Exos.
1.1 Fundamental Principles of Applied Biomechanics
1.2 Biomechanical Analysis of Human Movement
1.3 Design and Function of Exos: Types and Technologies
1.4 Selection of Exos: Criteria and Methodologies
1.5 Applications of Exos in Rehabilitation and Strength Training
1.6 Evaluation of Exo Effectiveness: Metrics and Analysis
1.7 Case Studies: Implementation of Exos in Real-World Settings
1.8 Ethical and Regulatory Considerations in the Use of Exos
1.9 Future Trends in Biomechanics and Exos
1.10 Final Project: Design and Strategic Application of an Exo
- 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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