Diploma in Architecture and Packaging for Micromobility
Sobre nuestro Diploma in Architecture and Packaging for Micromobility
The Diploma in Architecture and Packaging for Micromobility focuses on the comprehensive design of sustainable urban mobility solutions. It addresses the creation of lightweight, efficient, and safe vehicles, integrating industrial design, materials engineering, and packaging strategies. Aspects such as ergonomics, aesthetics, functionality, and sustainability are explored, with a focus on space optimization and user experience. The program also includes the study of regulations and market trends, preparing professionals to lead innovation in the micromobility sector. Practical skills development is guaranteed through the use of CAD design, simulation, and prototyping tools, enabling the creation of specific packaging solutions for vehicle transport and storage. The program delves into life cycle analysis and the selection of sustainable materials, fostering a comprehensive and responsible approach. This training fosters careers as product designers, packaging engineers, urban mobility specialists, and entrepreneurs in the field of micromobility.
Target keywords (natural in the text): micromobility, vehicle design, packaging, urban mobility, sustainability, industrial design, sustainable materials, ergonomics, life cycle, sustainable mobility, diploma.
Diploma in Architecture and Packaging for Micromobility
- 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
849 $
Competencias y resultados
Qué aprenderás
1. Design and Packaging of Micromobility Vehicles: Architecture and Packaging
- Understand the fundamental principles of micromobility vehicle architecture.
- Explore different micromobility vehicle configurations and designs.
- Analyze key components, including chassis, propulsion, and control systems.
- Learn about materials and manufacturing processes suitable for micromobility.
- Study the efficient packaging of components and systems in compact vehicles.
- Develop skills in interior design and ergonomics for micromobility.
- Consider safety and regulations in vehicle design and packaging.
- Evaluate the environmental impact and sustainability of micromobility.
- Use computer-aided design (CAD) tools for vehicle design.
- Apply simulation and analysis techniques to optimize the design.
2. Architectural Design and Packaging of Micromobility Vehicles
- Understand the principles of architectural design for micromobility vehicles, including material selection and structural configuration.
- Analyze the different types of micromobility vehicles: electric scooters, electric bicycles, unicycles, etc.
- Study the key factors in the packaging of these vehicles, including space optimization, ergonomics, and aesthetics.
- Learn about the relevant regulations and standards for the design and manufacture of micromobility vehicles.
- Become familiar with emerging technologies and market trends in the field of micromobility.
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. Architecture, Design, and Packaging for Micromobility: A Comprehensive Approach [The text abruptly switches to a seemingly unrelated topic:] ``
4. Architecture, Design, and Packaging for Micromobility: A Comprehensive Approach
- Understand current and future trends in the design of micromobility vehicles, including electric scooters, electric bicycles, and other personal devices.
- Analyze the key aspects of the architecture of these vehicles, from material selection to component layout and systems integration.
- Apply user-centered design principles to optimize ergonomics, safety, and the riding experience.
- Explore packaging strategies to maximize space efficiency and visual aesthetics, considering the need for integrated batteries, electronics, and other components.
- Evaluate different materials and manufacturing processes, such as the use of lightweight composites, to improve performance, durability, and sustainability.
- Develop skills in using design and simulation tools to optimize the structural and aerodynamic performance of vehicles.
- Implement energy management strategies and charging systems to maximize range and efficiency.
- Analyze relevant safety regulations and standards for micromobility and design vehicles that meet these requirements.
- Investigate innovation opportunities in areas such as connectivity, artificial intelligence, and the integration of renewable energy.
- Understand the environmental impact of micromobility and design solutions that minimize the carbon footprint.
5. Architecture and Packaging Optimization for Micromobility: Performance and Design [The text abruptly shifts to a seemingly unrelated topic: "]
- Master the analysis of suspension and steering systems for micromobility.
- Evaluate the integration of batteries and propulsion systems in the design.
- Optimize aerodynamics and drag in lightweight vehicles.
- Apply ergonomic and user-centered design principles.
- Understand the selection of advanced materials (composites, lightweight alloys).
- Implement efficient and sustainable manufacturing techniques.
- Study thermal management and safety in component packaging.
- Analyze the integration of sensors and control systems.
- Design structures resistant to vibrations and dynamic loads.
- Apply simulation methodologies and finite element analysis (FEA).
6. Optimizing Design and Packaging for Micromobility: Component Modeling
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 Architecture and Packaging for Micromobility
- Professionals with experience in the design, development, or implementation of urban mobility solutions, especially those interested in the design and functionality of micromobility vehicles.
- Industrial designers, architects, product engineers, and packaging professionals who wish to expand their knowledge in micromobility product design.
- Entrepreneurs and professionals seeking to develop or improve their skills in designing innovative micromobility products.
- Individuals interested in the study and application of sustainable materials and manufacturing processes, user-centered design, and space optimization in the field of micromobility.
- 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.
1.1 Introduction to Micromobility: Definition and Scope
1.2 Types of Micromobility Vehicles: Scooters, Electric Bicycles, etc.
1.3 Architectural Design Principles for Micromobility
1.4 Packaging Fundamentals for Micromobility Vehicles
1.5 Materials and Components in Micromobility: Selection and Considerations
1.6 Safety and Regulations Applicable to Micromobility
1.7 Ergonomic Design in Micromobility: Comfort and Usability
1.8 Aesthetic Design and Branding in Micromobility Vehicles
1.9 Sustainability and Life Cycle of Micromobility Products
1.10 Case Studies: Examples of Successful Architecture and Packaging
1.10
2.2 Introduction to Micromobility Vehicle Architecture and Design
2.2 Material Selection and Manufacturing Processes
2.3 Chassis and Vehicle Structure Design
2.4 Component Integration: Motor, Battery, and Control Systems
2.5 Interior Design and User Ergonomics
2.6 Packaging Design and Component Protection
2.7 Design Considerations for Sustainability and Environmental Impact
2.8 Modeling and Simulation: Tools for Micromobility Design
2.9 Cost Analysis and Design Feasibility
2.20 Case Studies: Examples of Successful Micromobility Designs
2.3
3.3 Material Selection and Manufacturing Processes for Micromobility Vehicles
3.2 Structural Design: Principles and Applications in Micromobility Vehicles
3.3 Stress and Deformation Analysis in Micromobility Structures
3.4 Packaging Design: Protection, Transport, and Storage
3.5 Component Integration: Space Optimization and Ergonomics
3.6 Design for Sustainability: Recycled Materials and Eco-Friendly Processes
3.7 Modular Design: Flexibility and Ease of Maintenance
3.8 Testing and Validation: Prototyping and Performance Analysis
3.9 Regulations and Standards: Compliance and Safety in Packaging Design
3.30 Case Studies: Examples of Successful Designs and Challenges in the Industry
3.4
4.4 Fundamental Concepts: Introduction to Micromobility and its Architecture
4.2 Conceptual Design: Defining Objectives, Target Audience, and Design Constraints
4.3 Material Selection: Evaluating Sustainable and High-Performance Materials
4.4 Structural Design: Principles of Strength, Stiffness, and Safety in Construction
4.5 Component Design: Integration of Electrical, Mechanical, and Electronic Systems
4.6 Packaging and Ergonomics: Designing the Human-Machine Interface and Available Space
4.7 3D Modeling and Prototyping: Creating Digital Models and Physical Prototypes
4.8 Testing and Validation: Verifying the Design through Testing and Simulation
4.9 Sustainability and Life Cycle: Environmental Considerations and the Circular Economy
4.40 Future Trends: Innovations in Micromobility Design and Architecture
5.5 Introduction to Micromobility: Definition and Trends
5.5 Structural Design for Micromobility: Materials and Strength
5.3 Efficient Packaging: Components and Space Distribution
5.4 Body Design and Aesthetics: Form and Function
5.5 ​​Ergonomics and User Experience: Comfort and Accessibility
5.6 Sustainability and Circular Design: Environmental Impact
5.7 3D Modeling and Prototyping: Tools and Techniques
5.8 Regulatory Aspects and Standards: Safety and Compliance
5.9 Case Studies: Examples of Successful Designs
5.50 Future Trends: Innovation in Micromobility
6.6 Component Modeling: Material and Process Selection
6.2 Design for Manufacturing: Cost and Feasibility Analysis
6.3 Structural Optimization: Finite Element Analysis (FEA)
6.4 Packaging Design: Protection and Space Efficiency
6.5 Component Modeling: Parametric and Generative Design
6.6 Packaging Design: Ergonomics and User Experience
6.7 Performance Analysis: Simulation and Validation
6.8 Design Optimization: Iteration and Feedback
6.9 Component Integration: Modular Design
6.60 Packaging Life Cycle Assessment (LCA)
6.7
7.7 Key Concepts of Architecture and Packaging in Micromobility
7.2 Materials and Sustainability in Packaging Design
7.3 Design of Components and Integrated Systems
7.4 Ergonomics and User Experience in Packaging
7.7 3D Modeling and Packaging Prototyping
7.6 Space Optimization and Compact Design
7.7 Applicable Regulatory Aspects and Standards
7.8 Design for Manufacturing and Assembly
7.9 Product Life Cycle Assessment (LCA) in Micromobility
7.70 Future Trends and Innovation in Packaging
8.8 Introduction to Micromobility Vehicle Design: Key Concepts
8.8 Fundamentals of Micromobility Vehicle Architecture
8.3 Design and Packaging Principles for Micromobility
8.4 Materials and Manufacturing Processes for Micromobility
8.5 Structural Design and Component Analysis
8.6 Modeling and Simulation of Micromobility Vehicles
8.7 Propulsion System and Energy Management Design
8.8 User-Centered Design and Ergonomics
8.8 Component Integration and Space Optimization
8.80 Prototyping and Testing of Micromobility Vehicles
9.9 Introduction to Micromobility: Definition, evolution, and trends.
9.9 The role of design in micromobility: Functionality, aesthetics, and user experience.
9.3 Types of micromobility vehicles: scooters, electric bicycles, kick scooters, etc.
9.4 The micromobility market: Opportunities and challenges.
9.5 Design methodology: research, ideation, prototyping, and testing.
9.6 Design tools and software: Introduction to CAD and 3D design.
9.9 Conceptual design: Defining objectives, target audience, and needs.
9.9 Architectural design: Design principles for micromobility vehicles.
9.3 Ergonomics and usability: User-centered design.
9.4 User interface (UI) and user experience (UX) design. 9.5 3D Model Conceptualization: Creation of sketches and initial models.
9.6 Styles and Trends: Influences on micromobility design.
3.9 Material Selection: Properties and characteristics of common materials.
3.9 Packaging Structure: Design for protection and durability.
3.3 Prototype Design: Use of materials, methods, and testing.
3.4 Sustainability and Recyclable Materials: Environmental considerations.
3.5 Trials and Tests: Ensuring material quality.
3.6 Standards and Regulations: Compliance with requirements.
4.9 Component Integration: Design and placement of key elements.
4.9 Propulsion Systems: Motors, batteries, and control systems.
4.3 Mechanical Component Design: Chassis, suspension, and steering.
4.4 Electrical System Design: Wiring, lighting, and safety. 4.5 Packaging Design: Component Design, Optimization, and Transportation
4.6 Aesthetic Considerations: Exterior Design, Finishes, and Customization
5.9 Design Optimization: Structural Analysis
5.9 Performance Analysis: Testing and Simulations
5.3 Weight Reduction: Principles and Techniques
5.4 Cost Analysis: Component Optimization
5.5 Optimization Strategies: Design Adjustments to Improve Performance
5.6 Design for Manufacturing: Considerations for Mass Production
6.9 3D Modeling: Modeling Software and Techniques
6.9 Component Modeling: Modeling Individual Elements
6.3 Model Assembly: Integrating Components into the Model
6.4 Virtual Prototype Design: Model Analysis and Simulation
6.5 Animation and Rendering: Creating Realistic Visualizations 6.6 Design Review and Validation: Testing and Correction
7.9 Structural Analysis: Evaluation of the architecture’s strength and durability
7.9 Performance Simulation: Motion and force simulation
7.3 Thermal Analysis: Heat control and dissipation
7.4 Architectural Modeling: Prototype design
7.5 Model Testing and Validation: Model usage
7.6 Design and Performance Optimization
8.9 Packaging Design: Design and planning
8.9 Packaging Material Selection
8.3 3D Packaging Modeling: Design for protection and aesthetics
8.4 Space Optimization: Design for efficient transport
8.5 Label Design: Information selection
8.6 Design for recycling and sustainability
9.9 Road Safety and Micromobility Legislation 9.9 Technical regulations for micromobility vehicles.
9.3 Safety standards and certifications.
9.4 Safety design regulations.
9.5 Environmental and sustainability regulations.
9.6 Accessibility and universal design.
9.7 Liability and insurance.
9.8 Compliance and risk management.
9.9 Case studies: Compliance analysis.
9.90 Future perspectives: Legislative developments.
1.1 Micromobility Design and Packaging: Introduction to Vehicle Architecture
1.2 Key Components and Functionalities in Vehicle Design
1.3 Material Selection and Sustainable Design Considerations
1.4 Structural Design: Chassis, Body, and Components
1.5 Packaging Design: Space Allocation and Components
1.6 Propulsion Systems and Their Integration into the Design
1.7 Human-Machine Interface (HMI) Design
1.8 Ergonomic and Safety Considerations
1.9 Design Standards and Regulations
1.10 Case Studies: Design and Packaging Analysis of Existing Vehicles
2.1 Micromobility Architecture: Fundamental Principles
2.2 Packaging Design: Space, Functionality, and Aesthetics
2.3 Aerodynamic Considerations in Design
2.4 Integration of Electrical and Electronic Systems
2.5 Material Selection and Manufacturing Processes
2.6 Weight Optimization and Energy Efficiency
2.7 Design for Sustainable Urban Mobility
2.8 User-Centered Design: Accessibility and Experience
2.9 Design for Mass Production
2.10 Design Examples: Analysis of Products on the Market
3.1 Structure and Design: Analysis of Reduced Mobility
3.2 Packaging Design for Micromobility: Specific Considerations
3.3 Structural Design and Strength of Materials
3.4 Modular Design and Adaptability in Vehicles for Reduced Mobility
3.5 Design of Propulsion and Control Systems
3.6 Design of Interfaces and Controls: Accessibility
3.7 Safety and Stability Considerations
3.8 Component Design: Seats, Handlebars, and Supports
3.9 Design for Transport and Storage
3.10 Case Studies: Design of Solutions for Reduced Mobility
4.1 Architecture, Design, and Packaging: An Integrated Approach
4.2 Architectural Design: Principles and Applications
4.3 Packaging Design: Component Integration
4.4 Material Selection and Manufacturing Processes
4.5 Propulsion Systems and Energy Management
4.6 Interior Design and Ergonomics
4.7 Safety Considerations and Regulatory Compliance
4.8 Sustainable Design and Product Life Cycle
4.9 Integration of Smart Technologies and Connectivity
4.10 Case Studies: Design and Packaging in Innovative Vehicles
5.1 Architecture and Packaging Optimization: Design and Performance
5.2 Vehicle Structure Design and Analysis
5.3 Packaging Optimization: Space Allocation and Components
5.4 Airflow Analysis and Aerodynamic Design
5.5 ​​Weight Optimization and Energy Efficiency
5.6 Design for Manufacturing and Assembly
5.7 Simulation and Finite Element Analysis (FEA)
5.8 User-Centered Design: Usability and Experience
5.9 Testing and Design Validation
5.10 Case Studies: Optimization in Practice
6.1 Design and Packaging Optimization: Component Modeling
6.2 3D Modeling of Components and Assemblies
6.3 Component Design: Motor, Batteries, Control Systems
6.4 Packaging Design: Component Distribution and Protection
6.5 Design Analysis: Structural Optimization
6.6 Simulation and Performance Analysis
6.7 Interface and Control Design
6.8 Material and Manufacturing Process Selection
6.9 Design Testing and Validation
6.10 Case Studies: Modeling and Simulation
7.1 Micromobility Architecture: Modeling and Design
7.2 Vehicle Architecture Design
7.3 Packaging Design Modeling
7.4 Structure and Body Design
7.5 Component Modeling and Simulation
7.6 Performance and Efficiency Analysis
7.7 Design Optimization
7.8 Ergonomic Design
7.9 Design for Sustainability
7.10 Case Studies: Design Analysis and Evaluation
8.1 Architecture and Packaging: Design and Modeling
8.2 Conceptual and Architectural Design
8.3 Packaging Design: Component Layout and Integration
8.4 3D Modeling: Design and Visualization
8.5 Structural Analysis and Simulation
8.6 Propulsion and Energy Management System Design
8.7 Safety Considerations and Regulations
8.8 Design for Manufacturing and Assembly
8.9 Design Prototyping and Testing
8.10 Case Studies: Micromobility Design in the Market
8.10
- 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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