Using the sensitive ears of a parasitic fly for inspiration, a group of researchers has created a new type of microphone that achieves better acoustical performance than what is currently available in hearing aids.
The scientists presented their results at the 21st International Congress on Acoustics, held June 2-7, 2013, in Montreal. The abstract and full text of their findings are available for download at www.asadl.org.
Ronald Miles, distinguished professor of mechanical engineering at Binghamton University, studies the hearing of Ormia ochracea, a house fly-sized insect that is native to the southeast United States and Central America. Unlike most other flies, O. ochracea has eardrums that sense sound pressure, similar to human ears, and they can hear “quite well,” says Miles. The female flies use their “remarkable” directional hearing to locate singing male crickets, on which they deposit their larvae.
Previously, Miles and colleagues Daniel Robert and Ronald Hoy described the mechanism by which the fly achieves its directional hearing, despite its small size. Now Miles and his group have designed a new microphone inspired by the fly’s ears.
The new design uses a microelectromechanical microphone with a 1 mm by 3 mm diaphragm that is designed to rotate about a central pivot in response to sound pressure gradients. The motion of the diaphragm is detected using optical sensors. To minimize the adverse effects of resonances on the response, Miles and his colleagues used a feedback system to achieve so-called active Q control.
Directional microphone in a mock behind the ear hearing aid package. The optical components, including the photodetectors and a semiconductor laser (VCSEL), are included on a circuit board that supports the directional microphone chip. | |
“Q control basically is an electronic feedback control system to introduce electronic damping,” Miles explains. “You don’t want a microphone diaphragm to ring like a bell. It turns out that in order to achieve a very low noise floor, which is the quietest sound that can be detected without the signal being buried in the microphone’s noise, it is important to minimize any passive damping in these sensors. If you do that, the diaphragm will resonate at its natural frequency. We are the first group to show that you can use this sort of electronic damping in a microphone without adversely affecting the noise floor of the microphone.”
The noise floor of the fly-inspired microphone is about 17 decibels lower than what can be achieved using a pair of low-noise hearing aid microphones to create a directional hearing aid. The new design could be used in applications ranging from hearing aids and cell phones to surveillance and acoustic noise control systems, Miles says, and “could easily be made as small as the fly’s ear.”
The presentation 2aEA1, “A biologically inspired silicon differential microphone with active Q control and optical sensing,” is available at www.asadl.org/poma/resource/1/pmarcw/v19/i1/p030031_s1?bypassSSO=1.