New Sound Diffuser Is 10 Times Thinner Than Existing Designs
For Immediate Release
Researchers from North Carolina State University and Nanjing University have developed an “ultra-thin” sound diffuser that is 10 times thinner than the widely used diffusers found in recording studios, concert venues and movie theaters to reduce echoes and improve the quality of sound. The new design uses less material, which would reduce cost, as well as taking up far less space.
In a typical room with flat walls, sound waves usually bounce off the walls, like light reflecting off a mirror. This creates echoes and overlapping sound waves that result in uneven sound quality depending on where you are in the room.
“Sound diffusers are panels placed on the walls and ceiling of a room to scatter sound waves in many different directions, eliminating echoes and undesirable sound reflections – ultimately improving the quality of the sound,” says Yun Jing, an assistant professor of mechanical and aerospace engineering at NC State and corresponding author of a paper on the work.
But the most widely used diffusers, called Schroeder diffusers, can be very bulky. That’s because the size of a diffuser is governed by the wavelength of the sound it needs to diffuse. Specifically, the depth of a Schroeder diffuser is about half of the wavelength of the lowest sound it needs to diffuse.
For example, a typical man’s voice can be as low as 85 hertz, with a wavelength of 4 meters or 13.1 feet. If that’s the lowest sound the Schroeder diffuser will have to deal with, the diffuser would need to be roughly 2 meters – or just over 6.5 feet – thick.
But the new, ultra-thin diffuser design requires a thickness that is only 5 percent of the sound’s wavelength. So, instead of being 2 meters thick, it would only be 20 centimeters – or less than 8 inches – thick.
“Diffusers are often made out of wood, so our design would use 10 times less wood than the Schroeder diffuser design,” Jing says. “That would result in lighter, less expensive diffusers that allow people to make better use of their space.”
This reduction in diffuser thickness is made possible by the design of the individual cells in the diffuser.
A Schroeder diffuser looks like a panel of evenly spaced squares, which are identical in length and width, but vary in depth.
The ultra-thin diffuser also consists of evenly spaced squares, but the squares appear to be of different sizes. That’s because each of the squares is actually an aperture that opens into a thin, underlying chamber. These chambers all have identical dimensions, but the size of the apertures varies significantly – accomplishing the same sound diffusion as the much larger Schroeder diffusers.
“We’ve built fully functional prototypes using a 3-D printer, and it works,” Jing says. “The design should work just as well using wood.”
The paper, “Ultra-thin Acoustic Metasurface-Based Schroeder Diffuser,” is published in the American Physical Society journal Physical Review X. Lead authors of the study are Yifan Zhu and Xudong Fan of Nanjing University. The paper was co-authored by Bin Liang and Jianchun Cheng of Nanjing University.
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Note to Editors: The study abstract follows.
“Ultra-thin Acoustic Metasurface-Based Schroeder Diffuser”
Authors: Yifan Zhu, Xudong Fan, Bin Liang and Jianchun Cheng, Nanjing University; Yun Jing, North Carolina State University
Published: June 5, Physical Review X
DOI: 10.1103/PhysRevX.7.021034
Abstract: “Schroeder diffuser” is a classical design, proposed over 40 years ago, for artificially creating optimal and predictable sound diffuse reflection. It has been widely adopted in architectural acoustics, and it has also shown substantial potential in noise control, ultrasound imaging, microparticle manipulation et al. The conventional Schroeder diffuser, however, has a considerable thickness on the order of one wavelength, severely impeding its applications for low-frequency sound. In this paper, a new class of ultrathin and planar Schroeder diffusers are proposed based on the concept of an acoustic metasurface. Both numerical and experimental results demonstrate satisfactory sound diffuse reflection produced from the metasurface-based Schroeder diffuser despite it being approximately 1 order of magnitude thinner than the conventional one. The proposed design not only offers promising building blocks with great potential to profoundly impact architectural acoustics and related fields, but it also constitutes a major step towards real-world applications of acoustic metasurfaces.
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