The continuous growth of STEM (Science, Technology, Engineering and Mathematics) education has set intense pressure on well-established engineering subjects, with a trend of replacing them with less demanding theoretical contents. This paper describes a recent activity with bachelor students to stimulate STEM education via a Robot-Sumo Competition. Students are grouped in teams to design, build and program their robot sumo robots. This course was implemented for the first time at University of Calabria (UNICAL). As a first attempt has been made with six teams each made of six students. Some seminars are delivered to the students to let them understand the assignment and its basic requirements. Then, they are expected to start developing a concept design and competition strategy. Then, they work on a 3D CAD modelling to design their own robot, whose main components will be later 3D printed and assembled. In parallel, the team selects the required sensors and electronic components as based on an Arduino architecture. The robots are completed and programmed for the competition where teams fight to find the most competitive solutions. The competition proves to be highly effective to learn multiple skills with a very practical and stimulating approach.
Citation: Giuseppe Carbone, Elio Matteo Curcio, Stefano Rodinò, Francesco Lago. A Robot-Sumo student competition at UNICAL as a learning-by-doing strategy for STEM education[J]. STEM Education, 2022, 2(3): 262-274. doi: 10.3934/steme.2022016
The continuous growth of STEM (Science, Technology, Engineering and Mathematics) education has set intense pressure on well-established engineering subjects, with a trend of replacing them with less demanding theoretical contents. This paper describes a recent activity with bachelor students to stimulate STEM education via a Robot-Sumo Competition. Students are grouped in teams to design, build and program their robot sumo robots. This course was implemented for the first time at University of Calabria (UNICAL). As a first attempt has been made with six teams each made of six students. Some seminars are delivered to the students to let them understand the assignment and its basic requirements. Then, they are expected to start developing a concept design and competition strategy. Then, they work on a 3D CAD modelling to design their own robot, whose main components will be later 3D printed and assembled. In parallel, the team selects the required sensors and electronic components as based on an Arduino architecture. The robots are completed and programmed for the competition where teams fight to find the most competitive solutions. The competition proves to be highly effective to learn multiple skills with a very practical and stimulating approach.
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Some pictures taken during the 3D printing classes and practices
Some pictures taken during the assembly and testing phase of the Sumo Robots
Robot of Team 1, called SQUARE
Robot of Team 2, called RHINO
Robot of Team 3, called J3RR1
Robot of Team 4, called JACKIE CHAN
Robot of Team 5, called BONAROBOT
Robot of Team 6, called DUNEBUGGY
Some photos taken during the competition
Photos taken during the final stage of the awards ceremony. 1: SQUARE, 2: RHINO, 3: J3RR1, 4: JACKIE CHAN, 5: BONAROBOT, 6: DUNEBUGGY