Platform-Page Demo

Our values are Transparency, inclusivity, sustainability (Laurent) Design a communication device that can be trusted by anyone anywhere (Laurent) Design a device that implies low budget, low tech sustainability (Laurent)

• Low-tech, repairable architecture
• Privacy-respecting features
• Transparent design and operation
• Universal accessibility regardless of user location or technical expertise
• Minimal environmental impact in production and use

Design

Assembly

• Conduct brainstorming sessions to generate innovative ideas.
• Define the device's purpose, functionality, and target audience.
• Sketching and storyboarding the chosen concept.
• Create concept sketches and mood boards to visualize ideas.

• Investigate existing technologies and market trends.
• Assess technical feasibility and resources availability.
• Identify potential challenges and propose solutions.
• Short tutorials on using digital fabrication tools, electronic components, and programming basics for those interested.

• Develop detailed CAD models of the device components.
• Design the user interface and experience (UI/UX).
• Ensure ergonomic and aesthetic considerations are met.
• Using available tools and materials in the fablab to create prototypes of their devices.

• Create electronic schematics and circuit layouts.
• Select appropriate microcontrollers, sensors, and communication modules.
• Design PCB layouts if necessary.

• Program the device's firmware and software applications.
• Implement communication protocols and data processing algorithms.
• Develop user interfaces if the device includes a display or app integration.

• Fabricate physical components using 3D printers, CNC machines, and laser cutters.
• Assemble the device, integrating electronic and mechanical parts.
• Use rapid prototyping techniques to iterate designs quickly.

• Perform functional testing to verify device operation.
• Conduct stress tests to assess durability.
• Collect data and feedback to identify areas for improvement.

• Engage potential users to test the device in real-world scenarios.
• Gather feedback on usability, functionality, and design.
• Make necessary adjustments based on user input.

• Refine the design and fix any remaining issues.
• Optimize the device for production or further development.
• Ensure compliance with relevant standards and regulations.
• Each team member presents their final phase and explains the design process and challenges encountered.

• Document the design process, including sketches, models, and code.
• Create user manuals, assembly guides, and technical specifications.
• Prepare presentations and reports to showcase the project.

• Develop a compelling presentation to share the project with stakeholders.
• Demonstrate the device's capabilities and features.
• Discuss potential next steps or commercialization opportunities.

• ·       Proficiency in computer-aided: manufacturing tools such as 3D printers, laser cutting, digital embroidery and milling machines for object production.

• 3D modeling skills for prototyping parts and customized objects.
• Experience with 3D printers, CNC machines, and laser cutters.

• 3D modeling skills are essential for creating digital models to be 3D printed or laser cut, whether for the design of individual parts in a technical project or for artistic projects.
• ·       Material selection and processing knowledge (plastics, metals, wood).
• ·       Necessary skills for creating prototypes and customized objects before manufacturing.

• ·       Imagine - Innovate: This also involves innovation, i.e. the ability to transform the existing to reconfigure it into a new identity.
• ·       Unpredictable, but adapted to needs and context.
• ·       Taking risks - recycling - adapting - transforming - inventing
• ·       Demonstrate curiosity            
• ·       Know how to mobilize resources (knowledge, know-how, materials, etc.).
• ·       Stand out from the crowd - don't follow the beaten track.
• ·       Be able to build projects to reach new goals.
• ·       Commitment - determination
• ·       Demonstrate persistence.
• ·       Demonstrate flexibility and adaptability

• Basic understanding of electronic components (resistors, capacitors, microcontrollers).
• Circuit design and schematic creation.
• Soldering and assembling electronic circuits.

• Identify local actors and their roles. 
• Be aware of the profiles, roles, and level of participation of others in the ecosystem.       
• Know how to negotiate, trade, and establish partnerships.              
• Situate yourself and deal with the constraints of the environment.
• Know how to structure your work with local resources. 
• Ability to think innovatively and develop unique solutions.
• Design thinking approach to address user needs.

• Proficiency in programming microcontrollers (e.g., Arduino, Raspberry Pi).
• Knowledge of programming languages like C++, Python, or embedded systems languages.
• Understanding of communication protocols (Bluetooth, Wi-Fi, GSM).
• Programming languages for the design and operation of software specific to digital manufacturing.
• Programming languages for software development and process automation.
• Applications in the creation of prototypes and customized products.

• Planning and organizing tasks effectively.
• Time management to meet project deadlines.
• Ability to coordinate and monitor collaborative digital projects within a digital manufacturing community.
• Interdisciplinary collaboration: Work effectively with professionals from various fields.
• Use of digital platforms that support interdisciplinary collaboration. Mastery of digital tools enabling remote working or facilitating collaborative project management.
• Managing process automation to optimize tasks using technology.
• Monitoring innovations to maintain competitiveness.
• Critical thinking: Evaluating information to make informed decisions.
• Collective management of equipment and infrastructure.
• Networking: Establish professional relationships to support the project.

• Ability to use CAD software (e.g.,SolidWorks, Fusion 360) for designing device components.

• Proficiency in specialized software

• Proficiency in programming languages for software development.

• Teamwork skills to work effectively in a group setting.
• Ability to communicate clearly and concisely, articulating ideas in a way that shares knowledge, both orally and in writing.
• Active listening
• Give constructive feedback.
• Clear communication to share ideas and feedback.

·       Promotion via social media: Using social platforms to reach a target audience.

·       Promotion via social media: Using social platforms to reach a target audience.

·       Word-of-mouth communication: Establishing interpersonal relationships to disseminate information.

·       Content creation (written, audio, video): Development of various media for promotion and education.

• ·       Data protection and securing digital systems.
• ·       Protecting digital systems and data against cyber threats.

• Cybersecurity: Courses to learn how to protect computer systems.

• Designing intuitive user interfaces and interactions.
• Empathy to understand user needs and preferences.

• Understanding of ergonomic design principles.
• Aesthetic design skills to enhance user appeal.

• Skills in testing prototypes and identifying issues.
• Attention to detail to ensure device reliability.
• Ability to analyze information and situations thoughtfully and make informed decisions.
• Development of critical digital thinking skills
• Introspection for personal development
• Ethical use of digital technologies and commitment to inclusion reinforce professionals' social responsibility, contributing to better collective performance.
• Ethical use of digital technology
• Leveraging digital for inclusion
• Community integration and belonging
• Testing and Quality Assurance