Fly lends an ear to microphone design
Peter Weiss
In the past decade, biologists discovered a new mechanism by which animals locate sounds. The finding emerged from the observation that a parasitic fly stalks crickets by sound, even though the fly's head is too small for any of the previously known sound-localization mechanisms to work. Now, engineers are creating a micro-microphone inspired by the fly's extraordinary ear.
Sounds make this heart-shaped fly ear teeter-totter and flap.
R. Hoy/Cornell Univ.
"The fly has given us an entirely different way of looking at microphone design," says Ronald N. Miles of the State University of New York at Binghamton.
For one thing, the new design strategy could lead to hearing aids that hide within a person's ear canal yet gather sound primarily from the direction the listener is facing, its developers say. It may also find use in battlefield-surveillance devices and yet more compact substitutes for microphones now used in cell phones and other communications gear.
Last year, a Canadian study showed that female flies of the species Ormia ochracea pinpoint sounds to within 2 compass degrees—as precisely as an owl does (SN: 11/11/00, p. 308). Owls, however, have large heads and ear-to-ear spacings big enough to exploit time delays and other indicators of a sound's direction, says Ronald R. Hoy of Cornell University, codiscoverer of the fly's unusual hearing apparatus.
The side-by-side eardrums of the fly span only about a millimeter. Unlike any other known ear structure, there's a bridge of stiff material connecting the two membranes almost as a hinge might, Hoy notes. Other small-headed animals, including birds and frogs, use an internal air tube between ears to discern direction information, he adds.
Colored simulation depicts fly-inspired diaphragm for microphones as it teeters up to the left.
R. Miles/SUNY Binghamton
Vibration studies by Miles, Hoy, and their colleagues have revealed that, because of its bridge, the fly ear responds to sound with mixtures of two motions: rocking like a teeter-totter and flapping like a wing. What's more, the location in the fly's ear structure of the peak amplitude from the vibrations reveals the direction of the sound source.
Using techniques for making microchips, the researchers have made a 1-mm-by-2-mm silicon diaphragm with a mechanical structure that resembles the fly ear's. While the device still lacks electrical pickups, it mimics the fly ear's motions, Miles says. He described the new device on Dec. 4 at the annual meeting of Acoustical Society of America in Fort Lauderdale, Fla.
The fly-inspired design "is breaking new ground in the area of acoustic sensing," says Edgar J. Martinez of the Defense Advanced Research Projects Agency in Arlington, Va., which helps fund the work.
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References:
Miles, R.N., et al. 2001. A silicon nitride microphone diaphragm inspired by the ears of the parasitoid fly Ormia ochracea. 142nd Meeting of the Acoustical Society of America. Dec. 4. Fort Lauderdale, Fla. Abstract available at http://asa.aip.org/web2/asa/abstracts/search.oct01/asa129.html.
Further Readings:
Milius, S. 2000. Psst. This fly's ears can rival a cat's. Science News 158(Nov. 11):308.
Sources:
Ronald R. Hoy
Department of Neurobiology and Behavior
Cornell University
Ithaca, NY 14853
Edgar R. Martinez
Microsystems Technology Office
Defense Advanced Research Projects Agency
3701 North Fairfax Drive
Arlington, VA 22203-1714
Ronald N. Miles
Mechanical Engineering Department
State University of New York, Binghamton
Binghamton, NY 13902-6000
From Science News, Volume 160, No. 23, December 8, 2001, p. 359.
