My Secret: How I Became an Autonomous Robotics Engineer

ubicoders

1 Oct 202408:05

Summary

TLDRIn this video, Elliot shares his journey of becoming a robotics engineer and offers practical advice for those interested in starting a robotics career. He emphasizes the importance of connecting three core concepts: math, code, and physical phenomena. Elliot explains how he struggled with math early on, but eventually succeeded by focusing on real-world applications, such as building a drone that recognizes human gestures. He introduces his upcoming course, 'Real Intro to Robotics 101,' designed for serious learners who want to bridge academic knowledge with practical experience in robotics engineering.

Takeaways

🤖 Robotics engineering involves designing, optimizing, and testing autonomous systems with algorithms like Visual Odometry, SLAM, and AI.
🔍 A key part of the work is data collection and testing, even though guidance on what data to collect may not always be clear.
📚 Starting a career in robotics often leads to overwhelming academic resources or programs that may not help beginners get started.
🔑 The key to success in robotics is learning to connect three main concepts: math, code, and physical phenomena.
📘 Textbooks and academic papers alone aren't enough; hands-on practice is essential for mastering robotics.
🛠 The speaker learned robotics through practical experience after struggling with math and seeking advice from experts.
🧠 The most important skill is being able to bridge the gap between theoretical knowledge (math), coding, and real-world application (physical phenomena).
🛸 A real-world example is solving the wobbling of a drone using a PID controller, which illustrates the need to connect math, code, and physical effects.
🎯 Robotics engineering can be categorized into three fields: Sensor Fusion, Control, and Decision-making.
📈 The speaker is preparing an in-depth robotics course called 'Real Intro to Robotics 101' for serious learners, covering advanced topics like 3D visual SLAM.

Q & A

What is the main focus of the video?
-The video focuses on how to become a robotics engineer, specifically how to design and optimize controllers for unmanned vehicles with autonomous navigation algorithms. It also discusses how to connect the core concepts of robotics: math, coding, and physical phenomena.
What challenges did the speaker face during college?
-The speaker struggled with sophomore-level math, particularly linear algebra, and had difficulty assembling robotics components, such as understanding how to connect wires on a drone.
How did the speaker overcome his difficulties with robotics and math?
-The speaker met a mentor who helped him focus on specific textbook chapters and practical applications. This guidance enabled him to bridge the gap between math, code, and real-world robotics phenomena, ultimately allowing him to achieve his dream project.
What was the speaker’s dream robotics project?
-The speaker’s dream project was a drone that could automatically take off and land by recognizing human gestures in real-time without the need for a remote controller.
How does the speaker categorize the field of robotics engineering?
-The speaker divides robotics engineering into three main areas: Sensor Fusion, Control, and Decision-Making. These areas involve combining data from various sensors, controlling physical components like robot motors, and making decisions for navigation and interaction.
What are the three main concepts the speaker emphasizes in robotics?
-The speaker emphasizes the importance of understanding and connecting three core concepts: math, coding, and physical phenomena. Mastering the relationship between these is key to becoming successful in robotics.
What advice does the speaker give for those just starting in robotics?
-The speaker advises beginners to focus on bridging the gap between math, code, and physical robotics. He recommends hands-on practice and understanding how theoretical knowledge applies to real-world phenomena.
What does the speaker’s online course offer?
-The speaker’s upcoming course, 'Real Intro to Robotics 101 for Serious People,' offers practical exercises in Sensor Fusion, Control, and Decision-Making, with a focus on real-world robotics applications. It includes complex projects such as controlling drones and performing 3D visual SLAM.
What is SLAM, and how does it relate to the speaker’s course?
-SLAM stands for Simultaneous Localization and Mapping. It involves a robot creating a real-time map of its environment without GPS. The speaker’s course covers 3D visual SLAM, which prepares students for serious robotics projects, unlike simpler 2D SLAM.
Who is the speaker’s course aimed at?
-The course is aimed at serious learners who are committed to starting a career in robotics. It’s designed for those who are overwhelmed by academic materials but want to engage in real robotics work, combining theory with hands-on practice.