Ad
South Korean scientists have developed swarms of microrobots that mimic ants’ collaborative behavior to accomplish tasks like transporting objects and guiding organisms. Credit:
Device/Yang and Won et al.
Microrobot swarms developed in South Korea achieve tasks like transporting objects and unclogging tubes using magnetic fields. Inspired by ants, these robots promise medical applications but need further autonomy advancements.
Scientists in South Korea have developed swarms of tiny magnetic robots that work together like ants to achieve Herculean feats, including traversing and picking up objects many times their size.
According to a study published on December 18 in the journal Device by Cell Press, the robots operate under a rotating magnetic field, enabling them to tackle complex challenges that would be difficult for single robots to manage. Potential applications include providing minimally invasive treatments for clogged arteries and precisely maneuvering biological samples in demanding environments.
High Adaptability and Performance in Tests
“The high adaptability of microrobot swarms to their surroundings and high autonomy level in swarm control were surprising,” says author Jeong Jae Wie of the Department of Organic and Nano Engineering at Hanyang University in Seoul, South Korea.
Wie and colleagues tested how well microrobot swarms with different assembly configurations performed at a variety of tasks. They found that swarms with high aspect ratio assembly could climb an obstacle five times higher than the body length of a single microrobot and hurl themselves, one by one, over an obstacle.
[embedded content]
Robots traversing lifting and guiding objects. Credit: Device/Yang and Won et al.
A large swarm of 1,000 microrobots with high packing density formed a raft that floated on water and wrapped itself around a pill that weighed 2,000 times more than each individual robot, enabling the swarm to transport the drug through the liquid.
On dry land, a robot swarm managed to transport cargo 350 times heavier than each individual, while another microrobot swarm was able to unclog tubes that resembled blocked blood vessels. Finally, through spinning and orbital dragging motions, Wie’s team developed a system through which robot swarms could guide the motions of small organisms.
Inspiration from Nature and Unique Design
Scientists have become increasingly interested in studying how swarms of robots can collectively achieve goals, inspired by the way ants band together to bridge a gap in a path or huddle in the shape of a raft to survive floods. Similarly, working together makes robots more resistant to failure—even if some members of the group fall short of the goal, the rest keep performing their programmed motions until enough of them eventually succeed.
[embedded content]
Guiding an ant and more. Credit: Device/Yang and Won et al.
“Previous swarm robotics research has focused on spherical robots, which come together through point-to-point contact,” says Wie. In this study, the researchers designed a swarm made up of cube-shaped microrobots, which share stronger magnetic attractions since larger surface areas—entire faces of each cube—can come into contact.
Each microrobot stands 600 micrometers tall and consists of an epoxy body embedded with particles of ferromagnetic neodymium-iron-boron (NdFeB), which enables it to respond to magnetic fields and interact with other microrobots. By powering the robots with a magnetic field generated by rotating two connected magnets, the swarm can self-assemble. The researchers programmed the robots to come together in different configurations by varying the angle at which the robots were magnetized.
“We developed a cost-effective mass production method using onsite replica molding and magnetization, ensuring uniform geometry and magnetization profiles for consistent performance,” says Wie.
“While the study’s results are promising, the swarms will need higher levels of autonomy before they will be ready for real-world applications,” says Wie.
“The magnetic microrobot swarms require external magnetic control and lack the ability to autonomously navigate complex or confined spaces like real arteries,” he says. “Future research will focus on enhancing the autonomy level of the microrobot swarms, such as real-time feedback control of their motions and trajectories.”
Reference: “Magnetic swarm intelligence of mass-produced, programmable microrobot assemblies for versatile task execution” by Kijun Yang, Sukyoung Won, Jeong Eun Park, Jisoo Jeon and Jeong Jae Wie, 18 December 2024, Device.
DOI: 10.1016/j.device.2024.100626
Ad
SomaDerm, SomaDerm CBD, SomaDerm AWE (by New U Life).