Preferred learners
- Anywhere
- Academic experience
Categories
Project scope
- What is the main goal for this project?
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The primary objective of this 80-hour project is to pave the foundational groundwork for a robotic delivery network. Emphasis is placed on the conceptualization, design, and development of a functional demo for individual working robots. The project aims to tackle core components, from formulating a robust software architecture to fine-tuning basic movement commands and safety measures like collision avoidance and battery management.
- What tasks will learners need to complete to achieve the project goal?
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By the culmination of the 80-hour time frame, students should manifest:
- An exhaustive and in-depth understanding of prevalent urban transportation solutions, giving weight to robotic interventions and how they shape the current market.
- Successfully architected a comprehensive software blueprint tailored for the delivery robot, ensuring flexibility and scalability.
- Proficiency in implementing elemental movement logic and a robust remote control mechanism that aligns with real-world scenarios.
- Seamless integration of safety protocols, prominently including a collision avoidance system and a meticulous battery monitoring setup.
- Diligent documentation and rigorous testing affirming the reliability and functionality of the assembled system.
- What is the main goal for this project?
-
The primary objective of this 80-hour project is to pave the foundational groundwork for a robotic delivery network. Emphasis is placed on the conceptualization, design, and development of a functional demo for individual working robots. The project aims to tackle core components, from formulating a robust software architecture to fine-tuning basic movement commands and safety measures like collision avoidance and battery management.
- What tasks will learners need to complete to achieve the project goal?
-
By the culmination of the 80-hour time frame, students should manifest:
- An exhaustive and in-depth understanding of prevalent urban transportation solutions, giving weight to robotic interventions and how they shape the current market.
- Successfully architected a comprehensive software blueprint tailored for the delivery robot, ensuring flexibility and scalability.
- Proficiency in implementing elemental movement logic and a robust remote control mechanism that aligns with real-world scenarios.
- Seamless integration of safety protocols, prominently including a collision avoidance system and a meticulous battery monitoring setup.
- Diligent documentation and rigorous testing affirming the reliability and functionality of the assembled system.
- How will you support learners in completing the project?
-
I am a product developer with 15 years of experience in automotive and will train, guide and mentor the intern to achieve the goal.
- What skills or technologies will help learners to complete the project?
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To adeptly navigate this project's intricacies, students should already have a grounding in:
- Robust review and research methodologies tailored for dissecting and understanding intricate technological ecosystems.
- The nuances of software architecture design highlight best practices and strategies that ensure adaptability and resilience.
- Fundamentals of robotics, particularly in areas of sensor orchestration, motor control dynamics, and real-time adjustments.
- Acquaintance with pivotal programming languages like Python or C++, ensuring a smoother developmental process.
- A working knowledge of prevalent communication protocols such as Bluetooth or Wi-Fi, facilitating seamless robot-control interactions.
Supported causes
About the company
- https://www.linkedin.com/company/telebotics/
- 2 - 10 employees
- Transport, trucking & railroad, Automotive, Technology
With a foundation in micromobility and the auto industry, we're revolutionizing deliveries with our network of automated robots. A fresh, scalable approach to logistics.