Researchers at Washington State University (WSU) have recently developed an extraordinary robotic bee named Bee++. This amazing creation represents a significant advancement in miniature robotics, providing the bee with full freedom of movement in all six degrees.
The robot’s four wings, constructed from carbon fiber and mylar, are controlled by a lightweight actuator, enabling stable flight in all directions, including the challenging twisting motion known as yaw.
Led by Néstor O. Pérez-Arancibia, the Flaherty associate professor at WSU’s School of Mechanical and Materials Engineering, the research team successfully published their findings on Bee++ in the esteemed journal IEEE Transactions on Robotics. Pérez-Arancibia is also scheduled to present their report at the upcoming IEEE International Conference on Robotics and Automation.
The development of Bee++ has been a long and ambitious journey, with researchers worldwide striving to create an artificial flying insect that can revolutionize various fields. The miniature robot holds great potential in artificial pollination, biological research, and search and rescue operations, particularly in confined environments like collapsed structures.
To bring the tiny robot to life, the researchers had to digitally recreate the intricate workings of an insect’s brain using specialized controllers. This fusion of robotic design and mathematical control, often referred to as the hidden technology, plays a crucial role in the bee’s successful operation.
In a significant breakthrough prior to Bee++, Pérez-Arancibia and his PhD students developed a four-winged insect robot capable of lifting off, pitching, and rolling, providing four degrees of freedom — however, controlling the yaw, the final two degrees of movement, proved to be an immense challenge. Overcoming this obstacle was crucial, as yaw control greatly expands the robot’s maneuverability and effectiveness.
With a weight of just 95mg and a 33mm wingspan, Bee++ is larger than an average bee but represents a significant step forward in the development of functional robots at this scale. The successful achievement of stable flight in all directions marks a major milestone and opens up exciting possibilities for the future of miniature robotics.
The creation of the robot bee by the WSU research team showcases the remarkable fusion of engineering, control systems, and mathematics required to achieve such a feat. As the field of robotic insects continues to evolve, Bee++ serves as a testament to human ingenuity and the limitless potential of technological advancements in shaping our world.