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'Folded' Optic Slims High-Res Cameras

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SAN DIEGO, Jan. 31, 2007 -- By "folding" a telephoto lens, engineers have built a powerful yet ultrathin digital camera. This technology may yield lightweight, ultrathin, high-resolution miniature cameras for unmanned surveillance aircraft, cell phones and infrared night vision applications.

EricTremblay.jpg"Our imager is about seven times more powerful than a conventional lens of the same depth," said Eric Tremblay, the first author on an Applied Optics paper to be published tomorrow and an electrical and computer engineering PhD candidate at the University of California, San Diego's Jacobs School of Engineering.

Tremblay is working with Joseph Ford, a professor of electrical and computer engineering at the Jacobs School who leads the camera project within UCSD's Photonic Systems Integration Lab. Ford is also affiliated with the UCSD division of the California Institute of Telecommunications and Information Technology, Calit2.

"This type of miniature camera is very promising for applications where you want high-resolution images and a short exposure time. This describes what cell phone cameras want to be when they grow up," said Ford. "Today's cell phone cameras are pretty good for wide angle shots, but because space constraints require short focal length lenses, when you zoom them in, they're terrible. They're blurry, dark and low contrast."

To reduce camera thickness but retain good light collection and high-resolution capabilities, Tremblay and colleagues replaced the traditional lens with a "folded" optical system that is based on an extension of conventional astronomical telescopes that employed mirrors, such as the Cassegrain telescope, which was developed in 1672.

"The folding idea was new in 1672, but they were doing it with two separate mirrors. We cut all of our reflective surfaces out of a single component and quadrupled the number of folds," said Ford.FoldedOptic.jpg
Top left: A conventional 35-mm camera lens. Right: The Montage Phase-1 folded imager described in the Feb. 2007 Applied Optics paper. Bottom left: A Montage Phase-2 folded imager, which is only mentioned in the current paper; it will be described in future publications. (Images: UC San Diego)
Instead of bending and focusing light as it passes through a series of separate mirrors and lenses, the new folded system bends and focuses light while it is reflected back and forth inside a single 5-mm-thick optical crystal. The light is focused as if it were moving through a traditional lens system that is at least seven times thicker.

"When all is said and done, our camera will look a lot like a lens cap that can be focused and used as a regular camera," said Ford. "Traditional camera lenses are typically made up of many different lens elements that work together to provide a sharp, high quality image. Here we did much the same thing, but the elements are folded on top of one another to reduce the thickness of the optic," said Tremblay. "Our 'folded lens' is not technically a lens, since it is reflective. I am guilty of calling it a lens sometimes, but I'm trying to control myself. 'Imager,' or 'folded optic' are more accurate."FoldedOpticLenses.jpg
Left: Diamond-turned optic before coating. Center: Silver-coated front surface with ring-shaped entrance pupil. Right: Coated back surface of the optic.
Folding the optic addresses performance issues facing today's cell phone cameras by increasing the "effective focal length" -- the zooming power of the camera -- without increasing the distance from the front of the optic to the image sensor. "The larger the number of folds in the imager, the more powerful it is," said Ford.

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On a disk of calcium fluoride -- a transparent optical crystal – the engineers cut a series of concentric, reflective surfaces that bend and focus the light as it is bounced to a facing flat reflector. The two round surfaces with 60-mm diameters are separated by 5-mm of transparent calcium fluoride.

This design strategy forces light entering the ring-shaped aperture to bounce back-and-forth between the two reflective surfaces. The light follows a predetermined zigzag path as it moves from the largest of the four concentric optic surfaces to the smallest and then to the CMOS light sensor. This kind of lens folding has not been widely implemented as a means to slim cameras, but recent advances in the mechanical machining process of "diamond turning" are changing that. The engineers used a diamond tip to cut all the reflective surfaces onto a single calcium fluoride disk.

"You mount the optic once and the diamond machining tool cuts all the optical surfaces without having to adjust the setup," said Tremblay. Not having to realign the optic during the machining of the reflective surfaces reduced an important source of error and helped make folding a viable approach for camera slimming.FoldedOpticDiagram.jpg
Above: cross section of an eightfold imager Below: cut-out view of the same imager. The blue lines illlustrate the path the light follows as it moves from aperture to light sensor. 
In mass production, diamond turning would be used to create a master for a molded-glass element, bringing the cost in line with the inexpensive molded glass aspheres found in current compact cameras. In the laboratory, the engineers compared a 5-mm-thick, 8-fold imager optimized to focus on objects 2.5 m away with a conventional high-resolution, compact camera lens with a 38-mm focal length. At best focus, the resolution, color and image quality are very similar between the two cameras, the authors report.

One initial drawback with the new folded camera was its limited depth of focus. Digital post-processing techniques and design changes were successfully implemented in the latest generation of the camera. The authors said that this latest generation of the technology will be covered in future publications.

The team is now designing variable-focus folded optical systems that have air between the reflective surfaces of the imager. Such imagers may be especially useful for lightweight, inexpensive infrared vision applications. The all-reflective systems also enable ultrabroad spectrum imaging and may be useful for ultraviolet lithography -- an emerging technique for squeezing more transistors onto silicon in order to create more powerful computer chips.

When asked about the likelihood of folded optics making their way into cell phone cameras, Tremblay said, "I don't know, but I'm hopeful. I think it's a good possibility." Picking up a domino-sized, next-next-generation prototype five times smaller than the disk shaped imager described in the paper, he said, "You can see how much smaller this has gotten already. It's going to keep shrinking."

This work is part of a larger multidomain optimization research team led by professor Mark Neifeld at the University of Arizona, which includes a related UCSD research effort on nanophotonics headed by professor Yeshaiahu Fainman.

This research is funded by DARPA through Dennis Healy's Montage program. To create fully-functional prototype imagers, the UCSD engineers partnered with Ron Stack and Rick Morrison of Distant Focus Corp., an optical systems company that designed the camera's electronic circuit boards and also developed the interface and control software.

For more information, visit: www.ucsd.edu

Published: January 2007
Glossary
calcium fluoride
An optical material used in place of crown glass to produce lenses with extraordinary correction of chromatic aberrations. Its high coefficient of thermal expansion and its tendency to absorb moisture limit its range of application.
focus
1. The focal point. 2. To adjust the eyepiece or objective of a telescope so that the image is clearly seen by the observer. 3. To adjust the camera lens, plate, or film holder so that the image is rendered distinct. 4. To move an entire microscope body tube relative to a specimen to obtain the sharpest possible image.
glass
A noncrystalline, inorganic mixture of various metallic oxides fused by heating with glassifiers such as silica, or boric or phosphoric oxides. Common window or bottle glass is a mixture of soda, lime and sand, melted and cast, rolled or blown to shape. Most glasses are transparent in the visible spectrum and up to about 2.5 µm in the infrared, but some are opaque such as natural obsidian; these are, nevertheless, useful as mirror blanks. Traces of some elements such as cobalt, copper and...
infrared
Infrared (IR) refers to the region of the electromagnetic spectrum with wavelengths longer than those of visible light, but shorter than those of microwaves. The infrared spectrum spans wavelengths roughly between 700 nanometers (nm) and 1 millimeter (mm). It is divided into three main subcategories: Near-infrared (NIR): Wavelengths from approximately 700 nm to 1.4 micrometers (µm). Near-infrared light is often used in telecommunications, as well as in various imaging and sensing...
light
Electromagnetic radiation detectable by the eye, ranging in wavelength from about 400 to 750 nm. In photonic applications light can be considered to cover the nonvisible portion of the spectrum which includes the ultraviolet and the infrared.
lithography
Lithography is a key process used in microfabrication and semiconductor manufacturing to create intricate patterns on the surface of substrates, typically silicon wafers. It involves the transfer of a desired pattern onto a photosensitive material called a resist, which is coated onto the substrate. The resist is then selectively exposed to light or other radiation using a mask or reticle that contains the pattern of interest. The lithography process can be broadly categorized into several...
nano
An SI prefix meaning one billionth (10-9). Nano can also be used to indicate the study of atoms, molecules and other structures and particles on the nanometer scale. Nano-optics (also referred to as nanophotonics), for example, is the study of how light and light-matter interactions behave on the nanometer scale. See nanophotonics.
photonics
The technology of generating and harnessing light and other forms of radiant energy whose quantum unit is the photon. The science includes light emission, transmission, deflection, amplification and detection by optical components and instruments, lasers and other light sources, fiber optics, electro-optical instrumentation, related hardware and electronics, and sophisticated systems. The range of applications of photonics extends from energy generation to detection to communications and...
reflective
The term reflective is an adjective that describes the ability of a surface or material to reflect light or other forms of radiation. It implies the capability of bouncing back or redirecting incident light waves. The reflective property is often quantified by the reflectivity or reflectance, which is the ratio of reflected light intensity to the incident light intensity. Key points about the term reflective: Surface property: When a surface is described as reflective, it means that the...
sensor
1. A generic term for detector. 2. A complete optical/mechanical/electronic system that contains some form of radiation detector.
ultraviolet
That invisible region of the spectrum just beyond the violet end of the visible region. Wavelengths range from 1 to 400 nm.
aspheresBiophotonicscalcium fluoridecamerasCMOSCommunicationsfiber opticsfocusfolded opticglassindustrialinfraredlenseslightlithographynanoNews & FeaturesOpticsphotonicsreflectivesensorSensors & DetectorsUCSDultrathinultravioletvision

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