Industry Briefing

A single destination for timely, editor-curated robotics news from around the world.

MIT's FloatForm Swarm Robots Create Adaptive Floating Structures for Urban Spaces

MIT's FloatForm Swarm Robots Create Adaptive Floating Structures for Urban Spaces

MIT researchers have developed FloatForm, a swarm of small robotic boats that autonomously assemble into larger floating structures. Each robot, measuring 21 centimeters square, is equipped with thrusters, sensors, and magnetic latches, allowing them to form bridges, platforms, and other structures with minimal human input. This innovative system aims to transform urban waterfronts into dynamic, programmable spaces, enhancing public infrastructure and emergency response capabilities. The significance of FloatForm lies in its potential to revolutionize how urban areas utilize water surfaces. By mimicking the self-organizing behavior of fire ants, the robots can adaptively create and reconfigure structures on demand, addressing challenges such as traffic alleviation during emergencies or creating temporary public spaces. This modular approach to floating infrastructure could lead to more livable cities by expanding usable public space onto underutilized water areas. Looking ahead, the research team plans to explore further applications of FloatForm in urban environments, with no specific timeline disclosed for future developments. The project builds on previous work with full-size autonomous vessels in Amsterdam, indicating a growing interest in leveraging water for urban mobility and public space expansion. The open-access findings were published in Nature Communications, highlighting the collaborative efforts of MIT's Computer Science and Artificial Intelligence Laboratory and the Senseable City Lab.

Research Robotics Autonomous vehicles Artificial intelligence Computer science and technology Machine learning
A new type of electrically driven artificial muscle fiber

A new type of electrically driven artificial muscle fiber

Researchers have developed electrofluidic fibers that replicate the natural bundling of muscle fibers, a breakthrough that could revolutionize the design of compact and silent robotic systems as well as prosthetics. This innovative technology was unveiled in a recent study aimed at enhancing the functionality and efficiency of robotic and prosthetic devices. By mimicking the structure and behavior of biological muscles, these fibers offer the potential for more responsive and adaptable machines. The advancement is particularly significant as it addresses the growing demand for quieter and more efficient robotic solutions in various applications, from medical devices to industrial automation. The research team employed advanced materials and engineering techniques to create these fibers, which could lead to a new generation of devices that are not only more effective but also more closely aligned with human movement. This development marks a promising step forward in the integration of robotics into everyday life, providing users with improved mobility and interaction capabilities.

Research Invention Robotics Bioinspiration Fluid dynamics Media Lab
RobotToday Initiative

Robotics needs a service framework.

RSF defines a common language for robot service capability, lifecycle operations, certification pathways, and service-provider networks.