Jan 24, 201209:00 AMPoint of View
The METROPOLIS Blog
Lab Report XIX
LEGO Mindstorms NXT 2.0, images via shop.lego.comThere is for example, the subject of science and how to help elementary school students understand difficult concepts, specifically those that relate to physicality. So the researchers asked themselves, how do children learn about physicality? Can their learning be influenced with the aid of programmable robots they, themselves, can manipulate? In the project GEAR, Grounded Embodied Agent Robots, the goal is to improve students’ engagement with basic physical scientific concepts. Using the LEGO Mindstorms NXT robots, researchers are teaching kids the concepts of force, mass, speed, distance, and friction. Normally, these lessons are reserved for more advanced classes, such as high school physics. (The research teams controlled for factors such as age, gender, and previous exposure to the scientific concepts being taught.) By using readily available robots already familiar to elementary school students the researchers did not need to spend time developing an entirely new device but could concentrate on finding the best teaching methods and investigating student responses to different approaches. Furthermore, lessons taught within the aid of a cool “toy” get the kids away from the sterile “scientific” environment.
LEGO Mindstorms NXT to teach programming, image via www.ilt.columbia.edu How to teach elementary school students programming concepts? The LEGO Mindstorms NXT robot provides the answer once more. HEAT, Handheld Embodied-cognition Augmented-reality Technology, teaches programming skills and also uses the idea of embodiment to frame the teaching strategies. In this case researchers were looking for ways to improve students’ “understanding of distance, time, and rate” through “technology-based interventions” that primarily involve hand-held devices for programming a robot’s movements. Ultimately, the goal was to improve learning by deploying embodiment principles, either directly, as when the students act like the robot and mimic the movements they, themselves, have programmed the robot to do. The other form of embodiment is through a surrogate, a handheld device that controls the robot. The hope is that the embodiment framework will improve the new generation’s ability to understand basic scientific concepts, from robotic programming to concepts in physics, like force and mass. Sherin Wing writes on social issues as well as topics in architecture, urbanism, and design. She is a frequent contributor to Archinect, Architect Magazine and other publications. She is also co-author of The Real Architect’s Handbook. She received her PhD from UCLA. Follow Sherin on Twitter at @xiaying. Previous Lab Reports - Lab Report Lab Report II Lab Report III Lab Report IV Lab Report V Lab Report VI Lab Report VII Lab Report VIII Lab Report IX Lab Report X Lab Report XI Lab Report XII Lab Report XIII Lab Report XIV Lab Report XV Lab Report XVI Lab Report XVII Lab Report XVIII