No matter how good our human designs may be, evolution has had a 4-billion-year head start, so there’s no shame in copying off Mother Nature’s homework. Engineers at the University of Bristol have ...

A computer model from Cornell University makes it easier to develop stably flying flapping robots.

Bio-inspired wind sensing using strain sensors on flexible wings could revolutionize robotic flight control strategy. Researchers have developed a method to detect wind direction with 99% accuracy ...

Robotics researchers regularly turn to the natural world for inspiration, and those working on machines that fly are no different. An international team of scientists has taken this approach to ...

Inspired by the remarkable flight capabilities of birds, bats, and insects, flapping-wing robotics represents one of the most promising frontiers in bio-inspired aerial systems, demonstrating enhanced ...

The study of bio-inspired flapping flight and the dynamics of micro air vehicles (MAVs) has grown into a vibrant interdisciplinary field, merging insights from insect biomechanics, aerodynamics and ...

(Nanowerk News) A new drive system for flapping wing autonomous robots has been developed by a University of Bristol team, using a new method of electromechanical zipping that does away with the need ...

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A new drive system for flapping wing autonomous robots has been developed, using a new method of electromechanical zipping that does away with the need for conventional motors and gears. A new drive ...