WASHINGTON, Oct. 2, 2013—For hundreds of years, optical devices like telescopes and microscopes have relied on solid lenses that slide up and down to magnify and to focus. To tune how much light is received, conventional devices use mechanical contraptions like the blades that form the adjustable aperture in cameras. To meet demands for ever smaller imaging systems, researchers are working to create entirely unconventional ways of focusing light. In pursuit of this vision, engineers from the University of Freiburg in Germany have built a novel type of imaging system inspired by the elegance and relative mechanical simplicity of the human eye. The technology may one day lead to new imaging instruments and microscopes for use in medicine and scientific research, such as devices for detecting early signs of skin cancer or early visual cues for food spoilage.
The new imaging system is the first to demonstrate the imaging capabilities of some of these unusual focusing techniques by replacing conventional, solid lenses with the combination of a malleable lens and a liquid iris-like component. And, the researchers report, their device focuses light almost as well as its biological counterpart in people. They describe their new imaging system in a paper published today in The Optical Society's (OSA) journal Optics Letters.
Though the image processing that happens in the human brain and eye is complex, the mechanical apparatus is relatively simple. It consists of muscles that deform a stretchable lens to change the focal length, the distance between the lens and the point at which rays of light are brought to a focus. The eye's iris opens and closes to control the amount of light that can pass through the lens.
But as engineers try to shrink the size and expand the capabilities of these instruments, the imaging systems they create become overly complex and expensive. Instead of using complicated mechanisms that require moving parts to tune the focus and adjust the aperture, the Freiburg researchers looked to the eye.
"What we're doing now is a completely different means of doing the tuning," said Hans Zappe, the Gisela and Erwin Sick Professor of Micro-optics at the University of Freiburg and coauthor of the paper.
For their new device, the researchers used two imaging elements that they had demonstrated previously but had never combined into a single system. They made a lens of silicone surrounded by several miniaturized motors that adjust the focus by deforming the lens.
"You can squeeze and stretch it just like your eye squeezes and stretches its lens to adjust its focal length," Zappe explained.
In front of the lens they included an iris-like component, which contains two liquids enclosed in a single flat chamber. One liquid is opaque and surrounds the clear liquid, forming what looks like a donut of black ink. Because the clear liquid is oil-based while the dark liquid is water-based, they stay separated. And since both liquids have exactly the same density, they remain in place even if you shake or rotate the device.
Applying an electrical voltage to these liquids changes some of their properties, such as the way a droplet beads up on a surface. This behavior, called electrowetting, allowed the researchers to manipulate the liquid, expanding and contracting the dark ring to let in more or less light through the clear liquid at the center.
Zappe and his team have tested and characterized the optics of their device in detail, analyzing how much it would distort an image. Each of the two main components – the iris-like liquids and the deformable lens – can be designed to compensate for any aberrations in the other, resulting in better optical quality than would be expected if you were to consider the two components separately, Zappe said. While the new device may not be as good as the best conventional visual imagers, it is the state of the art for a tunable lens, he said.
The cylindrical device described in the new paper is roughly three centimeters in diameter and five centimeters long, and although the researchers plan to shrink the design a bit more, making a miniature version isn't their primary goal, since optical quality is inherently limited with smaller sizes. Instead, Zappe said, they hope to add more functionality.
"What we're looking at is to make really high-quality images where we have the ability to image things that a normal person wouldn't be able to see," he explained.
Paper: "Miniaturized tunable imaging system inspired by the human eye," S. Schuhladen et al., Optics Letters, Vol. 38, Issue 20, pp. 3991-3994 (2013).
EDITOR'S NOTE: Images are available to members of the media upon request. Contact Lyndsay Meyer, firstname.lastname@example.org.
About Optics Letters
Published by The Optical Society (OSA), Optics Letters offers rapid dissemination of new results in all areas of optics with short, original, peer-reviewed communications. Optics Letters covers the latest research in optical science, including optical measurements, optical components and devices, atmospheric optics, biomedical optics, Fourier optics, integrated optics, optical processing, optoelectronics, lasers, nonlinear optics, optical storage and holography, optical coherence, polarization, quantum electronics, ultrafast optical phenomena, photonic crystals, and fiber optics. This journal, edited by Alan E. Willner of the University of Southern California and published twice each month, is where readers look for the latest discoveries in optics. Visit http://www.OpticsInfoBase.org/OL.
Founded in 1916, The Optical Society (OSA) is the leading professional society for scientists, engineers, students and business leaders who fuel discoveries, shape real-world applications and accelerate achievements in the science of light. Through world-renowned publications, meetings and membership programs, OSA provides quality research, inspired interactions and dedicated resources for its extensive global network of professionals in optics and photonics. For more information, visit http://www.osa.org.
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