There are no powered spinning propellers in nature. When evolution has found an advantage to producing thrust in a fluid, it has done it mainly by flapping things back and forth. This new VTOL ...

A simulation study was initiated to investigate alternative wing and flap controls for tilt-wing aircraft. The initial phase of the study compared the flying qualities of both a conventional ...

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 ...

Flapping-wing micro air vehicles (FWMAVs) are characterized by their compact size, lightweight design, and high maneuverability, making them highly practical for various applications. However, the ...

The wing dynamics of flying animal species have been the inspiration for numerous flying robotic systems. While birds and bats typically flap their wings using the force produced by their pectoral 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 ...

Bio-inspired wind sensing using strain sensors on flexible wings could revolutionize robotic flight control strategy. Researchers at Institute of Science Tokyo have developed a method to detect wind ...

(Nanowerk News) Engineers have long sought to unlock the secrets behind insects' uncanny flight abilities and agility in hopes of creating a new class of tiny yet capable flying robots. These flapping ...

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 ...

Zabdiel Avives flew across New York, gliding over and around buildings on the landscape — but the 12-year-old boy only had to travel about a dozen miles from his Maywood home for the experience. He ...