Intelligent and autonomous mobility systems
Dresden, Germany, November 22, 2024: Research Associates Yikai Zeng and Xinyu Zhang talk with us about the future of autonomous mobility and intelligent transportation systems that promise to redefine how we think about movement and connectivity in urban spaces.
Connected, cooperative and autonomous mobility
We talked with Yikai Zeng and Xinyu Zhang from the Chair of Traffic Process Automation at TU Dresden about their research and teaching activities, and how Duckietown is used at the MiniCCAM lab to teach autonomous mobility.
Hello and welcome! May I ask you to start by introducing yourself?
X. Zhang: Hi! I will start! My name is Xinyu. I’m a Research Associate at TU Dresden and currently work on computational basics and tools of traffic process automation. That’s why I got involved in this Duckiedrone demonstration. Apart from that, I am also responsible for the basic autonomous driving courses, where we use Duckiebots as our learning materials and tools for the students.
Y. Zeng: Hello, My name is Yikai. I’m also a Research Associate at TU Dresden, in Prof. Meng Wang’s laboratory.
Thank you very much, when did you first discover Duckietown?
Y. Zeng: the idea came from Professor Wang, who asked us to continue the Control course of a former colleague, using among other things, Duckiebots. When we took over the course, it was during the Covid period. Right now we have developed the MiniCCAM lab.
Could you tell us more about the miniCCAM lab?
Y. Zeng: Sure! The scope of the miniCCAM laboratory, for us researchers in the transportation and autonomous mobility field, is to look at the greater picture in terms of urban mobility, so slightly different in terms of scope than the course previously mentioned. We use Duckietown for autonomous driving. The current miniCCAM lab is on one hand a good tool for demonstrating to students and general audiences what we are able to do in terms of future transportation systems; on the other hand, it provides us with an opportunity to conduct research. For example, we implemented a higher logic controller for intersection navigation and tested it in both a simulated environment and on the model smart-city Duckietown setup. Duckietown is very practical because organizing an actual field test would be very expensive.
That's great to hear. Why did you decide to use Duckiebots to teach autonomous mobility?
Y. Zeng: The decision was taken before us, but I heard stories about that time. So this course has a long history, over ten years, and every few years the course was redesigned.
Around 2019 the decision was taken to upgrade our fleet of robots, and among various solutions, we also chose Lego initially, but it didn’t work very well for us.
So my former colleague found out about Duckietown, and that’s when the choice was taken. It came all in a single box, and this was considered very positive. It also came with complete teaching materials and very well-structured courses already. This was considered to be extremely useful to help us organize our courses, we just needed to modify what was already there for our own context. So this would be the main motivation, it’s very easy to deploy course materials, and the economic aspects were considered to be very attractive.
X. Zhang: Duckiebots are also good because they come with a camera and wheel encoders, making it easier to get students started, and having them learn about the fundamentals of autonomous driving.
It came all in a single box, complete teaching materials and very well-structured courses. This was considered to be extremely useful, we just needed to modify what was already there for our own context.
Did students appreciate using Duckiebots?
Y. Zeng: Certainly Duckietown succeeded as a teaching tool, attracting many students to our courses. I would say Duckietown has this characteristic of motivating and capturing the attention of many students. It also provides the first real hands-on experience in the field of robotics and autonomous mobility.
In our course on Computational basics and tools of traffic process automation (Rechentechnische Grundlagen und Werkzeuge der Verkehrsprozessautomatisierung), we use Duckiebots to teach students about general control, group control, and swarm control. Duckietown is also the main, shall we say, “tourist attraction” of our department. Every time we hold events, many students come to us to see the Duckiebots cooperating, going through intersections, and so forth. We’ve been using Duckietown for two years, and already it is very popular, inspiring many interesting discussions with our audiences with scientific backgrounds.
Much more efficient than a simple presentation, I’d say!
Duckiebots come with a camera and wheel encoders, making it easier to get students started, and having them learn about the fundamentals of autonomous mobility.
Would you recommend Duckietown to colleagues and students?
Y. Zeng: Yes absolutely, in fact, I’m a bit sad that you’re not producing the old model anymore! We definitely want to try the latest models, test them as a fleet, and introduce them to our lab in the future. Our main focus is always on the interaction between groups of bots and how they work together.
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