Diploma in Autonomous HMI Validation with Users and Regulators
Sobre nuestro Diploma in Autonomous HMI Validation with Users and Regulators
The Diploma in Autonomous HMI Validation with Users and Regulators focuses on the creation and certification of human-machine interfaces (HMIs) for autonomous systems, covering user interaction and regulatory compliance. It explores methodologies for user-centered design, user experience (UX) evaluation, and HMI safety and reliability validation in real-world scenarios. The program integrates user testing, usability analysis, and compliance with relevant safety regulations for autonomous systems, such as those in the automotive and aerospace industries. The program provides skills in the use of simulation and prototyping tools for HMIs, as well as in the application of design standards and certification processes. Participants are prepared for roles such as HMI engineers, UX analysts, autonomous system validation specialists, and functional safety consultants, enabling the development of safe and efficient autonomous systems. The ultimate goal is to secure approval by regulatory bodies.
Target keywords (natural occurrences in the text): Autonomous HMI, HMI validation, user-centered design, UX, usability, certification, autonomous systems, functional safety, safety regulations, regulatory bodies, human-machine interface.
Diploma in Autonomous HMI Validation with Users and Regulators
- 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
1.550 $
Competencias y resultados
Qué aprenderás
1. Autonomous Validation of HMIs: Regulatory Compliance and User Experience
- Understand the regulations and standards governing the validation of Human-Machine Interfaces (HMIs) in naval environments.
- Identify specific compliance requirements for HMIs, including safety, functionality, and performance standards.
- Evaluate the importance of user experience (UX) in the design and validation of naval HMIs.
- Analyze the implications of poor HMI design on safety, efficiency, and decision-making on board.
- Apply autonomous validation methods for HMIs, including functional testing, usability testing, and risk analysis.
- Utilize simulation tools and techniques to validate HMI performance in different operational scenarios.
- Develop a deep understanding of human factors and their impact on HMI interaction.
- Design and optimize HMIs to improve clarity, accessibility, and efficiency from the user.
- Integrate continuous validation into the HMI development lifecycle to ensure compliance and continuous improvement.
- Present and document HMI validation results in accordance with applicable regulations.
2. Design and Verification of Autonomous Interfaces: A Regulatory and User-Centered Approach
- Fundamentals of regulation for autonomous vehicles.
- User-centered design principles applied to autonomous interfaces.
- Techniques for the verification and validation of autonomous systems.
- Risk assessment and mitigation in interface design.
- Analysis of human-machine interaction in autonomous environments.
- Ethical and legal aspects related to autonomy.
- Design of intuitive and accessible interfaces.
- Testing and simulations to ensure safety and reliability.
- Implementation of control and monitoring systems.
- Application of simulation and modeling tools.
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. Mastering Autonomous HMI Validation: Regulatory Perspectives and User Experience
4. Mastery of Autonomous HMI Validation: Regulatory Perspectives and User Experience
- Understand the current regulatory framework for the validation of autonomous HMIs in the naval sector, including relevant national and international regulations.
- Identify the key components of an autonomous HMI and their interaction, including sensors, actuators, control systems, and the human-machine interface.
- Analyze user-centered design principles for creating intuitive and safe interfaces, considering the needs and capabilities of operators.
- Evaluate different validation methodologies, including simulator testing, laboratory testing, and real-world testing, to ensure the safety and reliability of the HMI.
- Apply simulation and modeling tools and techniques to predict HMI behavior in various operational situations and scenarios.
- Develop strategies for risk management and error mitigation in the HMI, considering the criticality of
- Become familiar with best practices in collecting and analyzing user data, including interviews, surveys, and usability testing, to continuously improve the user experience.
- Learn about the latest trends in HMI technology, including artificial intelligence, augmented reality, and voice control, and assess their potential to improve efficiency and safety in autonomous navigation.
- Understand the specific challenges of validating autonomous HMIs on different types of vessels and naval operations, such as merchant ships, offshore platforms, and underwater vehicles.
- Prepare for the certification and accreditation of autonomous HMIs by understanding the requirements and procedures established by the relevant authorities.
6. Autonomous HMI Validation: Design, Regulatory Compliance, and User Experience
6. **Autonomous HMI Validation: Design, Regulatory Compliance, and User Experience**
- Master the principles of human-machine interface (HMI) design for autonomous systems, focusing on clarity, intuitiveness, and efficiency.
- Understand and apply relevant international standards and regulations for the safety and performance of autonomous HMIs, including specific regulations for the marine industry.
- Evaluate and optimize the user experience (UX) of autonomous HMIs, using research, testing, and data analysis methods to ensure usability, accessibility, and user satisfaction.
- Learn to perform comprehensive validations of autonomous HMIs, including functional testing, performance testing, safety testing, and simulations in various operational scenarios.
- Develop skills in identifying and mitigating risks associated with autonomous HMIs, including design flaws, software failures, and Cyber ​​threats.
Become familiar with the key technologies used in autonomous HMIs, such as touchscreens, voice interfaces, augmented reality, and predictive control systems.
Apply the knowledge acquired in the design and validation of autonomous HMIs to specific case studies in the marine industry, such as navigation systems, propulsion control, and cargo management.
Ensure the interoperability and integration of autonomous HMIs with other onboard systems, guaranteeing seamless communication and efficient information management.
Understand the latest trends in the development of autonomous HMIs, including artificial intelligence, machine learning, and real-time data analytics.
Acquire the necessary skills for the documentation and maintenance of autonomous HMIs, including the creation of user manuals, test procedures, and preventive maintenance plans.
6. Diploma in Autonomous HMI Validation: User Experience, Regulatory Compliance, and Comprehensive Design
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 Autonomous HMI Validation with Users and Regulators
- 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 — Regulatory Foundations of Autonomous HMIs
1.1 Initial Regulatory Framework for Autonomous HMIs
1.2 User-Centered Design (UCD) Principles and their Regulatory Integration
1.3 Global Standards and Key Regulations for HMIs
1.4 Documentation and Regulatory Compliance Management
1.5 Risk and Security Analysis in Autonomous HMIs
1.6 User Experience (UX) in the Regulatory Context: Principles and Metrics
1.7 Introduction to HMI Verification and Validation
1.8 Accessibility and Usability Considerations in Regulated HMIs
1.9 Case Studies: Compliance Analysis and Regulatory Challenges
1.10 Future Trends in the Regulation of Autonomous HMIs
1.10
2.2 Introduction to Standalone HMI Design: Fundamental Principles and Regulatory Context
2.2 Fundamentals of User Experience (UX) in Standalone HMIs: User-Centered Design
2.3 Regulatory Requirements for Standalone HMI Design: Key Standards and Regulations
2.4 User Interface (UI) Design for Standalone HMIs: Design Principles and Best Practices
2.5 Verification and Validation of Standalone HMIs: Methodologies and Tools
2.6 Inclusive Design and Accessibility in Standalone HMIs: Considerations for All Users
2.7 Human Factors and Safety in Standalone HMI Design: Error Prevention
2.8 Iterative Design and Prototyping in Standalone HMIs: Agile Methodologies
2.9 Integration of Standalone HMIs into Complex Systems: Interoperability and Synchronization
2.20 Study of Case Studies: Analysis of Successful Autonomous HMIs and Lessons Learned
3.3 Fundamentals of Autonomous HMIs: Definitions and Regulatory Context
3.2 User-Centered Design Principles for Autonomous HMIs
3.3 Relevant Regulations and Standards for HMI Validation
3.4 Validation Methodologies: Usability and User Experience Testing
3.5 Tools and Techniques for Evaluating Autonomous HMIs
3.6 Risk Analysis and Mitigation in HMI Design
3.7 Design of Adaptive and Personalized Interfaces
3.8 Design for Accessibility and Universality in HMIs
3.9 Case Study: HMI Validation in Specific Environments
3.30 Documentation and Reporting of HMI Validation Results
4.4 Introduction to Autonomous HMI Validation: Fundamentals and Objectives
4.2 Regulatory Framework: Applicable Regulations and Industry Standards
4.3 User-Centered Design Principles: UX/UI for Autonomous HMIs
4.4 Validation Methodologies: Testing, Simulation, and Evaluation
4.5 User Experience: Interaction Design and Optimization
4.6 Regulatory Compliance: Ensuring Safety and Functionality
4.7 Autonomous HMI Validation Tools and Technologies
4.8 Case Studies: Analysis of Successful Autonomous HMIs and Challenges
4.9 Best Practices: Design, Implementation, and Validation
4.40 The Future of Autonomous HMI Validation: Trends and Advances
4.5
5.5 Regulatory Framework for HMI Interfaces in Aircraft
5.5 UX/UI Design Principles for Aeronautical Systems
5.3 Applicable Regulations for User Experience
5.4 User-Centered Interface Design
5.5 Usability Testing and Validation of UX Designs
5.6 Risk Analysis in UX Design
5.7 Visual Design and Accessibility in Aeronautical HMIs
5.8 Integrating User Feedback into the Design Process
5.9 UX Design Tools and Methodologies
5.50 Case Studies: Best Practices and Common Mistakes in UX Design
5.5 Design Principles for Autonomous Interfaces
5.5 Validation of Interfaces in Complex Systems
5.3 Regulatory Framework and Compliance in HMIs
5.4 User Interface Design for Autonomous Systems 5.5 Interface Verification and Validation
5.6 User-Centered Design for Standalone Interfaces
5.7 HMI Simulation and Testing Techniques
5.8 Data Integration and User Feedback
5.9 Design and Verification Tools
5.50 Case Studies: Interface Design and Validation
3.5 Fundamentals of HMI Validation
3.5 Interface Design Standards and Regulations
3.3 User-Centered Design and UX
3.4 Usability Testing and Design Validation
3.5 Risk Analysis in Validation
3.6 User Experience Optimization
3.7 Validation Tools and Methodologies
3.8 User Feedback Integration
3.9 HMI Validation Case Studies
3.50 Trends in HMI Validation
4.5 User Experience (UX) Principles
4.5 The Regulatory Framework in HMI Design
4.3 User-Centered Design
4.4 Risk Analysis and Mitigation
4.5 Validation and Verification of HMI Designs
4.6 Usability Testing and Evaluation
4.7 Tools and Technologies for HMIs
4.8 Integrating Feedback and Continuous Improvement
4.9 Case Studies of Successful HMIs
4.50 Challenges and Opportunities in HMI Design
5.5 Designing Autonomous HMIs
5.5 Regulatory Compliance
5.3 User-Centered Design (UX)
5.4 User Experience (UX)
5.5 Validation and Verification of HMI Designs
5.6 Usability Testing and Evaluation
5.7 Risk Analysis and Mitigation 5.8 Tools and Technologies for HMIs
5.9 Integrating Feedback and Continuous Improvement
5.50 Case Studies and Best Practices
6.5 User Experience (UX) Fundamentals
6.5 User Interface (UI) Design
6.3 Interaction Design (IxD) for HMIs
6.4 User-Centered Design Principles
6.5 Prototyping and Usability Testing
6.6 Evaluating Accessibility and Readability
6.7 Designing for Different Users and Contexts
6.8 Integrating Feedback and Iterative Design
6.9 Tools and Technologies for UX Design
6.50 Case Studies and Trends in UX
7.5 HMI Design Principles
7.5 Regulatory Framework and Compliance
7.3 User-Centered Design 7.4 Interface Testing and Verification
7.5 Risk Analysis and Mitigation
7.6 User Experience and Optimization
7.7 Design Tools and Methodologies
7.8 Feedback Integration and Continuous Improvement
7.9 Case Studies and Practical Examples
7.50 Future Trends in HMIs
8.5 Principles of Integrated Design
8.5 User Experience and UX
8.3 Regulatory Compliance
8.4 User-Centered Design
8.5 Interface Testing and Validation
8.6 Feedback Integration and Continuous Improvement
8.7 Design Tools and Technologies
8.8 Risk Analysis and Mitigation
8.9 Case Studies and Practical Examples
8.50 Future Trends and Innovative Design
6.6 Principles of Aircraft Navigation and Piloting
6.2 Structure and Operation of Flight Control Systems
6.3 Introduction to Aeronautical Regulations and Safety Standards
6.4 Human Factors in Interface Design and Their Impact on Safety
6.5 Components and Architecture of a Flight Display System
6.6 Fundamentals of Human-Machine Interaction (HMI) in Aviation
6.7 Principles of Interface Design for Aviation: Readability and Usability
6.8 Introduction to Flight Automation and Flight Management Systems
6.9 Risk Analysis and Safety Management in the Aeronautical Context
6.60 Regulatory Framework for Aircraft and System Certification
2.6 Fundamentals of User Experience (UX) and Its Importance in HMI Design
2.2 User Research Methodologies and Requirements Gathering 2.3 Designing Intuitive and User-Friendly Interfaces: Principles of Cognitive Psychology
2.4 User-Centered Design: Prototyping and Usability Testing
2.5 Visual Design and Graphical User Interface (GUI) Principles
2.6 Designing Adaptive and Customizable Interfaces for Different Environments
2.7 Accessibility Considerations in HMI Design
2.8 Designing Interfaces for Emergency and High-Stress Situations
2.9 Usability Evaluation and User Testing: Metrics and Analysis
2.60 Current Trends in HMI Design: Augmented and Virtual Reality in Aviation
3.6 Regulatory Framework for HMI Validation in Aircraft
3.2 International Standards and Regulations Applicable to HMI Validation
3.3 Validation Process: Validation Plan, Test Execution, and Reporting
3.4 Regulatory Compliance Testing and Requirements Verification 3.5 Usability testing: evaluating effectiveness, efficiency, and user satisfaction.
3.6 Designing realistic test scenarios and use cases.
3.7 Validating interfaces in simulated and real-world environments.
3.8 Risk analysis and error mitigation in HMIs.
3.9 Documentation and configuration management of HMIs.
3.60 HMI certification and approval: requirements and processes.
4.6 Advanced validation methodologies for autonomous HMIs.
4.2 Model-based validation: simulation and analysis of complex systems.
4.3 Artificial intelligence and machine learning in autonomous HMIs: challenges and opportunities.
4.4 Validation of perception and decision-making systems in autonomous HMIs.
4.5 Verification and validation of autonomous flight control systems.
4.6 Designing specific security tests and risk analyses for autonomous systems. 4.7 Cybersecurity in Autonomous HMIs: Protection against threats and vulnerabilities.
4.8 Robustness and reliability testing of autonomous HMIs.
4.9 Integration of autonomous HMIs into air traffic control systems.
4.60 Future of autonomous HMI validation: Trends and challenges.
5.6 Regulatory framework and standards for HMI design and validation.
5.2 User-centered design principles: Requirements and expectations.
5.3 Designing intuitive and secure interfaces: Human factors and ergonomics.
5.4 Implementing usability testing and evaluating user experience.
5.5 Validating performance and security requirements.
5.6 Regulatory compliance testing and standards verification.
5.7 Designing and validating interfaces for different operational scenarios.
5.8 Risk management and error mitigation in HMI design. 5.9 HMI Configuration Documentation and Management
5.60 HMI Certification and Approval: Requirements and Processes
6.6 UX Principles and Their Application in Aviation HMI Design
6.2 Regulatory Compliance and Applicable Regulations for Aeronautical HMIs
6.3 Designing Intuitive, Safe, and Efficient Interfaces
6.4 Usability Testing and User Experience Evaluation
6.5 Validation of Safety and Performance Requirements
6.6 Designing HMIs for Different Operational Scenarios
6.7 Risk Management and Error Mitigation in HMI Design
6.8 HMI Configuration Documentation and Management
6.9 HMI Certification and Approval Process
6.60 Future Trends in HMI Design and Validation
7.6 HMI Design: Architecture, Components, and Technologies
7.2 Regulations and Standards Applicable to HMI Design and Validation
7.3 Verification and Validation Methodologies: Functional Testing, Performance Testing, and Usability Testing
7.4 Requirements Management and Traceability
7.5 Test Design and Use Cases
7.6 User Experience (UX) Evaluation
7.7 Risk Analysis and Error Mitigation
7.8 Documentation and Configuration Management
7.9 Integration and Validation Testing on Real Systems
7.60 HMI Certification and Approval
8.6 UX Principles and Their Application in HMI Design
8.2 Designing Intuitive and User-Friendly Interfaces
8.3 User-Centered Design Methodologies
8.4 Usability Testing and User Experience Evaluation 8.5 Compliance with applicable regulations and standards.
8.6 HMI design for different operational scenarios.
8.7 Risk management and error mitigation in HMI design.
8.8 HMI documentation and configuration management.
8.9 HMI certification and approval process.
8.60 Future trends in HMI design and validation.
7.7 Introduction to Aeronautical Regulations and Rotorcraft
7.2 UX Design Principles in Aeronautical Environments
7.3 User-Centered Design Requirements Analysis
7.4 Application of UX Standards in Rotorcraft HMIs
7.7 Interface Design and User Flows for Helicopters
7.6 Usability and Accessibility Principles in HMIs
7.7 Usability Testing and HMI Evaluation
7.8 User-Centered Design and UX Validation
7.9 Iteration and Continuous Improvement in UX Design
7.70 Case Studies: Rotorcraft HMIs and UX Design
2.7 Fundamentals of HMI Design for Autonomous Systems
2.2 Standards and Regulatory Guidelines for Autonomous HMIs
2.3 User-Centered Design Principles in Autonomous HMIs
2.4 Interface Design and Data Visualization in Systems Autonomous HMIs
2.7 Validation and Verification of Autonomous HMIs
2.6 Simulation Testing and Evaluation of HMIs
2.7 Integration of Sensor and System Data into HMIs
2.8 Safety and Reliability Considerations in HMI Design
2.9 Risk Analysis and Mitigation in Autonomous HMIs
2.70 Case Studies: Autonomous HMI Design and Validation
3.7 Regulatory Framework for HMI Validation
3.2 User-Centered Design Principles for HMIs
3.3 User Requirements Gathering and Analysis
3.4 User Interface and Experience Design
3.7 Implementation of Validation Tests
3.6 Usability Test Design
3.7 Data Analysis and Validation Results
3.8 HMI Design Iteration and Improvement
3.9 Validation Documentation and Reports
3.70 Case Studies: HMI Validation and UX
4.7 Introduction Regulation in Standalone HMIs
4.2 UX Principles and their Application in Standalone HMIs
4.3 Interface Design and User Experience
4.4 Usability and Accessibility Evaluation
4.7 Regulatory Compliance and Applicable Standards
4.6 Implementation of Validation Tests
4.7 Results Analysis and Continuous Improvement
4.8 Risk Management in HMI Design
4.9 HMI Documentation and Certification
4.70 Case Studies: UX and HMI Regulation
7.7 HMI Design Principles
7.2 Regulatory Compliance in HMI Design
7.3 Interface Design and User Experience
7.4 Validation and Verification Process
7.7 Usability Testing and Evaluation
7.6 Data Analysis and Results
7.7 Risk Management in Design
7.8 Implementation and Documentation
7.9 Case Studies: Design and Compliance
7.70 Integration HMI
6.7 User Experience (UX) Fundamentals
6.2 User-Centered Design Principles
6.3 User Research and Analysis
6.4 User Interface (UI) Design
6.7 Usability Testing and Evaluation
6.6 Accessibility in HMI Design
6.7 Prototyping and Iteration
6.8 Visual Design and Branding
6.9 Responsive Design
6.70 Case Studies: HMI Design and User Experience
7.7 Introduction to Comprehensive HMI Verification
7.2 Interface Design for Autonomous Systems
7.3 Regulatory Requirements and Standards
7.4 Verification and Validation Testing
7.7 Risk Management in HMI Design
7.6 Usability and Accessibility Evaluation
7.7 Prototype Design and Development
7.8 Data Analysis and Continuous Improvement
7.9 Documentation and Regulatory Compliance
7.70 Case Studies: Design and HMI Regulation
8.7 Principles of Integrated HMI Design
8.2 User Experience (UX) in HMIs
8.3 User Interface (UI) Design
8.4 Regulatory Requirements and Standards
8.7 Validation and Verification Process
8.6 Usability Testing and Evaluation
8.7 Risk Management in Design
8.8 Implementation and Documentation
8.9 Case Studies: Integrated Design and Experience
8.70 Future Trends in Autonomous HMIs
8.8 HMI Design Fundamentals: Principles and Standards
8.8 HMI Architecture: Components and Functionalities
8.3 User-Centered Design: Methodologies and Tools
8.4 Design Validation: Testing and Evaluation
8.5 Regulatory Compliance: Regulations and Guidelines
8.6 User Experience (UX): Design for Efficiency and Safety
8.7 Comprehensive Design: Iteration and Continuous Improvement
8.8 Adaptive Interface Design
8.8 HMI Validation and Simulation Tools
8.80 Case Studies: Examples of HMI Validation
8.8
9.9 Regulatory Requirements for HMIs in Aircraft and Autonomous Systems
9.9 User-Centered Design and User Experience (UX) Principles in HMIs
9.3 Compliance Standards and Regulations Applicable to HMI Validation
9.4 Risk Analysis and Mitigation in HMI Design
9.5 Usability Testing and Validation of HMIs to Ensure Safety and Efficiency
9.6 Accessibility Considerations in HMI Design
9.7 Case Studies of HMIs and Their Impact on User Experience
9.8 Designing Adaptive Interfaces for Different Operational Scenarios
9.9 Importance of Documentation and Traceability in Regulatory Compliance
9.90 Human Factors and Human-Machine Interaction (HMI)
9.9 Specific UX/UI Design Principles for Autonomous HMIs
9.9 Tools and Software for Interface Design
9.3 User flow design and prototyping.
9.4 Visual design of HMIs, including icon and graphic element design.
9.5 Interaction and feedback design.
9.6 Design for different user types and operational scenarios.
9.7 Implementation of responsive and adaptive design.
9.8 UX/UI usability evaluation and testing techniques.
9.9 Future trends in HMI design.
9.90 Integration of UX/UI design with regulatory requirements.
3.9 Key regulations and standards for HMI validation.
3.9 Validation test design, including performance and security testing.
3.3 User-centered design in the validation process.
3.4 Simulation and laboratory testing for HMIs.
3.5 Data analysis and validation results. 3.6 Security and Data Protection Aspects in HMIs
3.7 Designing Validation Reports and Documentation
3.8 Validation and Verification Methodologies
3.9 Integrating Validation into the Development Lifecycle
3.90 Optimizing the User Experience Through Validation
4.9 Global Regulatory Frameworks and Their Impact on HMI Validation
4.9 Applying Regulations in Design and Development
4.3 User Risk Analysis and User-Centered Design
4.4 Advanced Validation Techniques and Methodologies
4.5 Emerging Tools and Technologies in Validation
4.6 Analysis of Validation Data
4.7 Integrating Validation and Agile Development
4.8 Validation Documentation and Management
4.9 Continuous Improvement of Validation Processes 4.90 Special Considerations for HMIs in Standalone Systems
5.9 Designing HMIs to Meet Regulatory Requirements
5.9 Applying Regulations in HMI Design and Development
5.3 User-Centered Design and User Experience
5.4 Tools and Software for Design and Validation
5.5 ​​Validation Testing, Including Performance and Security Testing
5.6 Analysis of Validation Data and Results
5.7 Designing Validation Reports and Documentation
5.8 Implementing Validation in the Development Lifecycle
5.9 Security and Cybersecurity Considerations in HMIs
5.90 Optimizing the User Experience in HMIs
6.9 UX/UI Design for Standalone HMIs
6.9 User Experience and Design Principles
6.3 User Flow Design and Prototyping 6.4 Compliance with regulatory requirements.
6.5 Design and validation tools.
6.6 Validation testing, including performance and security testing.
6.7 Analysis of validation data and results.
6.8 Design of validation reports and documentation.
6.9 Design lifecycle management.
6.90 Integration of design, UX, and regulation.
7.9 HMI design: principles and best practices.
7.9 Verification and validation requirements.
7.3 Simulation and validation testing.
7.4 Design of verification reports and documentation.
7.5 Regulatory aspects and industry standards.
7.6 Verification methodologies.
7.7 Analysis of verification data and results.
7.8 Integration of verification into the development lifecycle.
7.9 Design of adaptive and flexible interfaces.
7.90 Security and Cybersecurity Considerations
8.9 User-Centered HMI Design
8.9 User Experience and Design Principles
8.3 Compliance with Regulatory Requirements
8.4 Validation Testing, Including Performance and Security Testing
8.5 Data Analysis and Validation Results
8.6 Design of Validation Reports and Documentation
8.7 Design Lifecycle Management
8.8 Security and Cybersecurity Considerations
8.9 Design and Validation Tools
8.90 Integrating Design, UX, and Regulation
9.9 UX/UI Design Principles for HMIs
9.9 User Flow Design and Prototyping
9.3 Validation Requirements
9.4 Validation Testing, Including Performance and Security Testing
9.5 Data Analysis and Validation Results 9.6 Designing validation reports and documentation.
9.7 Managing the design and validation lifecycle.
9.8 Design and validation tools.
9.9 Integrating UX/UI design and validation.
9.90 Security and cybersecurity considerations.
1. HMI Validation: Introduction to UX/UI Design
2. Fundamental Principles of UX/UI Design for HMIs
3. User-Centered Interface Design
4. HMI Design and Prototyping
5. UX/UI Design: High-Fidelity Interface Design
6. Regulatory Requirements and Standards for HMI Validation
7. Usability and User Experience Testing
8. HMI Validation: Implementation and Evaluation
9. UX/UI Validation Tools and Methodologies
10. Final Project: UX/UI Integration and HMI Validation
- 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.