Remote Data Collection System Strapped To a Dragonfly
Duke University electrical engineers have developed a wirelessly powered telemetry system that is light weight and powerful enough to allow scientists to study the intricate neurological activity of dragonflies as they capture prey on the wing.
Past studies of insect behavior have been limited by the fact that remote data collection, or telemetry, systems were too heavy to allow the insects to act naturally, as they would in the wild. The new system uses no batteries; its power is beamed wirele...
Duke University electrical engineers have developed a wirelessly powered telemetry system that is light weight and powerful enough to allow scientists to study the intricate neurological activity of dragonflies as they capture prey on the wing.
Past studies of insect behavior have been limited by the fact that remote data collection, or telemetry, systems were too heavy to allow the insects to act naturally, as they would in the wild. The new system uses no batteries; its power is beamed wirelessly to the flying dragonfly.
Duke electrical engineer Matt Reynolds, working with Reid Harrison at Intan Technologies, developed the chip for scientists at the Howard Hughes Medical Institute (HHMI), who are trying to better understand the complex flight control system of dragonflies. They gather their information by attaching tiny electrodes to individual cells in the dragonfly’s nerve cord and recording the electrical activity of the dragonfly's neurons and muscles. Because existing systems are so heavy, experiments to date have been carried out with immobilized dragonflies.
“Our system provides enough power to the chip attached to a flying dragonfly that it can transmit in real time the electrical signals from many dragonfly neurons,” Reynolds said. The researchers expect this system will enable studying behavior of small animals remotely for the first time.
Reynolds, an assistant professor of electrical and computer engineering at Duke’s Pratt School of Engineering, presented his work today at the annual Biomedical Circuits and Systems Conference, held by the Institute of Electrical and Electronics Engineers (IEEE) in San Diego.
The wireless power transmitter works within a flight arena used for the experiments. It can send enough power to the chip to enable it to send back reams of data at over five megabits per second, which is comparable to a typical home Internet connection. This is important, the scientists said, because they plan to sync the neuronal data gathered from the chip with high-speed video taken while the insect is in flight and preying on fruit flies.
“Capturing this kind of data in the past has been exceedingly challenging,” said Anthony Leonardo, a neuroscientist who studies the neural basis of insect behavior at HHMI’s Janelia Farm Research Campus in Virginia. “In past studies of insect neurons, the animal is alert, but restrained, and observing scenarios on a projection screen. A huge goal for a lot of researchers has been to get data from live animals who are acting naturally.”
The average weight of the dragonfly species involved in these studies is about 400 milligrams, and Leonardo estimates that an individual dragonfly can carry about one-third of its weight without negatively impacting its ability to fly and hunt. Currently, most multi-channel wireless telemetry systems weigh between 75 and 150 times more than a dragonfly, not counting the weight of the battery, which rules them out for most insect studies, he said. A battery-powered version of the insect telemetry system, previously developed by Harrison and Leonardo, weighs 130 milligrams -- liftable by a foraging dragonfly but with difficulty.
The chip that Reynolds and his team developed is just 38 milligrams, or less than half the weight of a typical postage stamp. That makes it one-fifth the weight of earlier telemetry systems, but with 15 times greater bandwidth, Reynolds said.
The researchers expect to begin flight experiments with dragonflies over the next few months. The testing will take place in a specially designed flight arena at HHMI's Janelia Farm complex equipped with nature scenes on the walls, a pond and plenty of fruit flies for the dragonflies to eat.
The chip, with two hair-thin antennae, will be attached to the belly of the insect so it does not interfere with the wings. Being carried like a backup parachute on the underside of the animal also gives it uninterrupted radio contact with the power transmitter on the ground.
The project is supported in part by the Howard Hughes Medical Institute. Duke graduate student Stewart Thomas was also a member of the team.
Originally posted at Pratt School of Engineering
Past studies of insect behavior have been limited by the fact that remote data collection, or telemetry, systems were too heavy to allow the insects to act naturally, as they would in the wild. The new system uses no batteries; its power is beamed wirelessly to the flying dragonfly.
Duke electrical engineer Matt Reynolds, working with Reid Harrison at Intan Technologies, developed the chip for scientists at the Howard Hughes Medical Institute (HHMI), who are trying to better understand the complex flight control system of dragonflies. They gather their information by attaching tiny electrodes to individual cells in the dragonfly’s nerve cord and recording the electrical activity of the dragonfly's neurons and muscles. Because existing systems are so heavy, experiments to date have been carried out with immobilized dragonflies.
“Our system provides enough power to the chip attached to a flying dragonfly that it can transmit in real time the electrical signals from many dragonfly neurons,” Reynolds said. The researchers expect this system will enable studying behavior of small animals remotely for the first time.
Reynolds, an assistant professor of electrical and computer engineering at Duke’s Pratt School of Engineering, presented his work today at the annual Biomedical Circuits and Systems Conference, held by the Institute of Electrical and Electronics Engineers (IEEE) in San Diego.
The wireless power transmitter works within a flight arena used for the experiments. It can send enough power to the chip to enable it to send back reams of data at over five megabits per second, which is comparable to a typical home Internet connection. This is important, the scientists said, because they plan to sync the neuronal data gathered from the chip with high-speed video taken while the insect is in flight and preying on fruit flies.
“Capturing this kind of data in the past has been exceedingly challenging,” said Anthony Leonardo, a neuroscientist who studies the neural basis of insect behavior at HHMI’s Janelia Farm Research Campus in Virginia. “In past studies of insect neurons, the animal is alert, but restrained, and observing scenarios on a projection screen. A huge goal for a lot of researchers has been to get data from live animals who are acting naturally.”
The average weight of the dragonfly species involved in these studies is about 400 milligrams, and Leonardo estimates that an individual dragonfly can carry about one-third of its weight without negatively impacting its ability to fly and hunt. Currently, most multi-channel wireless telemetry systems weigh between 75 and 150 times more than a dragonfly, not counting the weight of the battery, which rules them out for most insect studies, he said. A battery-powered version of the insect telemetry system, previously developed by Harrison and Leonardo, weighs 130 milligrams -- liftable by a foraging dragonfly but with difficulty.
The chip that Reynolds and his team developed is just 38 milligrams, or less than half the weight of a typical postage stamp. That makes it one-fifth the weight of earlier telemetry systems, but with 15 times greater bandwidth, Reynolds said.
The researchers expect to begin flight experiments with dragonflies over the next few months. The testing will take place in a specially designed flight arena at HHMI's Janelia Farm complex equipped with nature scenes on the walls, a pond and plenty of fruit flies for the dragonflies to eat.
The chip, with two hair-thin antennae, will be attached to the belly of the insect so it does not interfere with the wings. Being carried like a backup parachute on the underside of the animal also gives it uninterrupted radio contact with the power transmitter on the ground.
The project is supported in part by the Howard Hughes Medical Institute. Duke graduate student Stewart Thomas was also a member of the team.
Originally posted at Pratt School of Engineering