Cracking the mystery of how insects fly — with robots

Scientists build the first robot that can “fly” alongside flying insects — opening new doors to flight behavior research.

Even with the best fly-swatter skills, a buzzing insect is hard to pin down. Flies can hover, fly sideways and backward, and land upside down.

The acrobatics of flying insects has captivated scientists for decades, but much of the physics of insect flight remains a mystery. The tiny critters are just too damn fast.

But now there is a robot that can keep up.

Researchers from the CNRS, Université de Lorraine, and Inrae built the first cable-driven robot that can follow the movement of free-flying insects. With the robot — essentially a box with cameras, suspended by cables — researchers can capture videos or photos of natural flight behavior right alongside the insect.

The camera tracks the irregular flight pattern of the moth. Credit: Mélanie Jouaiti and Dominique Martinez

Insects might be the most advanced aerialists in the world. They were the first organisms to evolve flight. Most flies flap their wings 200 times each second. Mosquitoes beat theirs three times as fast — so fast they make that pesky humming sound. Mosquitoes can fly about 1.5 mph, while a dragonfly can reach speeds up to 35 mph.

Up until now, researchers had to study their flight using a stationary camera to capture take-off or landing. Some scientists tethered flying insects to a central location, called a flight mill, which allows them to measure flight capability, like speed or distance, in a circular path.

In 2002, Michael Dickinson, a biologist at UC Berkeley captured some of the fly’s agility using high-speed video cameras. He filmed the fly doing a maneuver called a saccade — a very rapid body turn. With the high-speed footage, Dickinson was able to break down the maneuver’s elements. Then, in 2014, scientists from the University of Oxford tethered a blowfly to a vertical mount and used x-rays to film inside its body during flight.

With tracking and stabilization abilities, the camera can film the moth in detail. Credit: Mélanie Jouaiti and Dominique Martinez

But to follow the irregular pattern of flying insects from take-off to landing and anywhere in between — well, it is no small task. This new robot could change that.

The researchers tested their robot with the Agrotis ipsilon, a common migratory moth found on nearly every continent. They equipped the robot with cameras and a controller to minimize tracking errors and followed the 2 cm moth up to a speed of 3 meters/second.

Their work, published in Science Robotics on 10 June, will help scientists understand flying insects’ locomotion and orientation strategies and how visual, olfactory, and other senses stimulate flight behavior.

Related
Meet the humanoids: 8 robots ready to revolutionize work
Everything you need to know about the humanoids that will soon enter the workforce — or are in it already.
Boston Dynamics retires dancing Atlas robot — and debuts its electric replacement
A day after retiring its hydraulic Atlas robot, Boston Dynamics released a video debuting its all-electric, workplace-ready replacement.
Does AI need a “body” to become truly intelligent? Meta researchers think so.
We’re finally starting to see what can happen when we put an advanced AI “brain” in a state-of-the-art robot “body” — and it’s remarkable.
Bipedal robot takes a beating, keeps on hiking
LimX Dynamics’s bipedal robot, P1, can keep its footing, even when traversing rough terrain unlike any it’s seen before.
Humanoid robots are joining the Mercedes-Benz workforce
German automaker Mercedes-Benz is deploying Apptronik’s Apollo robots at a manufacturing plant in Hungary.
Up Next
Construction Robotics
Exit mobile version