Myongji University Microsystems Laboratory Directed by Prof. Sang Kug Chung

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2015.04.23 (11:38:36)

(서울=연합뉴스) 권영전 기자 = 스마트폰의 본체보다 카메라 렌즈가 두꺼워 카메라 부분만 툭 튀어나온 이른바 '카툭튀'를 없앨 기술이 등장했다.


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31일 전자업계에 따르면 미국 하버드 공학응용과학대학(SEAS) 연구팀은 렌즈 두께를 획기적으로 줄일 수 있는 기술을 최근 개발했다고 홈페이지를 통해 공지했다.

새 기술은 평평한 유리 표면에 현미경으로나 관측할 수 있는 실리콘 안테나를 씌운 메타표면(metasurface) 렌즈를 이용하는 방식이다. 이 렌즈를 이용하면 미리 정해진 알고리듬에 따라 정확히 입사광을 굴절시킬 수 있다.

지금까지는 상당한 두께를 가진 렌즈 여러 개를 겹쳐서 사용했기 때문에 카메라의 두께가 스마트폰보다 두꺼웠다. 예컨대 아이폰6의 경우에도 사진 품질을 유지하기 위해 5개의 렌즈를 겹쳐 놓아야 했기 때문에 이른바 '카툭튀'가 생겨났다.

그러나 새 기술로 개발한 렌즈를 사용하면 아주 얇은 렌즈 하나만으로 같은 기능을 수행할 수 있다.

연구책임자(PI)인 페데리코 카파소 교수는 "전통적인 광학체계에서는 여러 개의 두꺼운 렌즈를 이용해야만 색보정과 같이 복잡한 효과를 줄 수 있었지만, (신기술을 이용하면) 매우 얇고 작은 기기만으로도 가능하다"고 말했다.

새 기술을 이용하면 신용카드 두께의 스마트폰에 들어갈 카메라 모듈도 만들 수 있다는 게 연구진의 설명이다.

다만 이 기술을 이용한 소비자 제품 상용화는 최소 5년 이상이 걸릴 것으로 예상된다.

comma@yna.co.kr

2015.04.23 (11:41:21)
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Perfect colors, captured with one ultra-thin lens

NO NEED FOR COLOR CORRECTION—HARVARD PHYSICISTS’ FLAT OPTICS, USING NANOTECHNOLOGY, GETS IT RIGHT THE FIRST TIME

February 19, 2015

Cambridge, Mass. – February 19, 2015 – Most lenses are, by definition, curved. After all, they are named for their resemblance to lentils, and a glass lens made flat is just a window with no special powers.

But a new type of lens created at the Harvard School of Engineering and Applied Sciences (SEAS) turns conventional optics on its head.

A major leap forward from a prototype device demonstrated in 2012, it is an ultra-thin, completely flat optical component made of a glass substrate and tiny, light-concentrating silicon antennas. Light shining on it bends instantaneously, rather than gradually, while passing through. The bending effects can be designed in advance, by an algorithm, and fine-tuned to fit almost any purpose.

With this new invention described today in Science, the Harvard research team has overcome an inherent drawback of a wafer-thin lens: light at different wavelengths (i.e., colors) responds to the surface very differently. Until now, this phenomenon has prevented planar optics from being used with broadband light. Now, instead of treating all wavelengths equally, the researchers have devised a flat lens with antennas that compensate for the wavelength differences and produce a consistent effect—for example, deflecting three beams of different colors by the same angle, or focusing those colors on a single spot.

“What this now means is that complicated effects like color correction, which in a conventional optical system would require light to pass through several thick lenses in sequence, can be achieved in one extremely thin, miniaturized device,” said principal investigator Federico Capasso, the Robert L. Wallace Professor of Applied Physics and Vinton Hayes Senior Research Fellow in Electrical Engineering at Harvard SEAS.

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Ordinary refractive lenses (left) suffer from significant chromatic aberrations as different wavelengths are focused in different spots. To compensate for this chromatic dispersion, additional lenses have to be added in an objective to compensate for chromatic aberrations as the number of wavelengths to be corrected increases. An achromatic doublet corrects for 2 wavelengths, an apochromat for 3 and finally a so called super-achromat for four wavelengths. The Harvard team's new metasurface lenses (right) are designed to focus light in the same spot for 3 different wavelengths with no need to increase the lens thickness and footprint. (Image courtesy of Patrice Genevet, Federico Capasso, and Francesco Aieta, Harvard SEAS.)


Bernard Kress, Principal Optical Architect at Google [X], who was not involved in the research, hailed the advance:

“Google [X], and especially the Google Glass group, is relying heavily on state-of-the-art optical technologies to develop products that have higher functionalities, are easier to mass produce, have a smaller footprint, and are lighter, without compromising efficiency,” he said. “Last year, we challenged Professor Capasso’s group to work towards a goal which was until now unreachable by flat optics. While there are many ways to design achromatic optics, there was until now no solution to implement a dispersionless flat optical element which at the same time had uniform efficiency and the same diffraction angle for three separate wavelengths. We are very happy that Professor Capasso did accept the challenge, and also were very surprised to learn that his group actually solved that challenge within one year.”

The team of researchers, led by Capasso and postdoctoral fellow Francesco Aieta, has developed a design that rivals the bulky equipment currently used in photography, astronomy, and microscopy. It could also enable the creation of new miniature optical communications devices and find application in compact cameras and imaging devices.

The new lens, dubbed an “achromatic metasurface,” dramatically improves on the flat lens Capasso’s research group demonstrated in 2012. That prototype, the first of its kind, corrected for some of the aberrations of conventional lenses but suffered from the limitation of only focusing light of a single wavelength, and its focusing efficiency was small. The new model uses a dielectric material rather than a metal for the nanoantennas, a change which greatly improves its efficiency and, combined with a new design approach, enables operation over a broad range of wavelengths.

Most significantly, the new design enables the creation of two different flat optical devices. The first, instead of sending different colors in different directions like a conventional grating, deflects three wavelengths of light by exactly the same angle. In the second device, the three wavelengths can all be focused at the same point. A flat lens can thus create a color image—focusing for example red, green, and blue, the primary colors used in most digital displays. The team’s computational simulations also suggest that a similar architecture can be used to create a lens that collimates many different wavelengths, not just three.

“This is a major step forward in establishing a planar optical technology with a small footprint which overcomes the limitations of standard flat optics, known as diffractive optics,” said Capasso. “It also opens the door to new functionalities because of the enormous design space made possible by metasurfaces.” “This is an elegant and groundbreaking accomplishment,” said Nader Engheta, H. Nedwill Ramsey Professor at the University of Pennsylvania, who was not involved in the research. “The planar optical structures designed and demonstrated by Professor Capasso's group have much less volume than their conventional bulky counterparts and at the same time their chromatic aberration has been suppressed. This is an important development that will undoubtedly lead to other exciting innovations in the field of flat photonics.”

Harvard's Office of Technology Development has filed for a provisional patent on the new optical technology and is actively pursuing commercial opportunities.

“Our previous work on the metallic flat lens produced a great excitement in regard to the possibility of achieving high numerical aperture and spherical aberration-free focusing with a very compact design. By demonstrating achromatic lenses we have now made a major step forward towards widespread future application of flat optics that will certainly attract the interest of the industry,” said lead author Francesco Aieta, now employed by Hewlett Packard, who conducted the research at Harvard SEAS.

Additional coauthors of the Science paper include Mikhail A. Kats and Patrice Genevet, both former members of the Capasso laboratory. Kats, who earned his Ph.D. at Harvard SEAS in 2013, is now an assistant professor at the University of Wisconsin, Madison. Genevet, formerly a postdoctoral research associate at SEAS, is now at the Singapore Institute of Manufacturing Technology.

This research was supported in part by a MURI grant from the Air Force Office of Scientific Research (FA9550-12-1-0389), with additional support from Draper Laboratory (SC001-0000000731), and the National Science Foundation (NSF, ECCS-1347251). Fabrication was performed at theHarvard Center for Nanoscale Systems, which is a member of the NSF-funded National Nanotechnology Infrastructure Network.


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In 2012, the research demonstrated a prototype flat lens that could create a perfectly focused image or a twisting vortex beam. In a major leap forward, announced in February 2015, the researchers have demonstrated that a metasurface can focus different wavelengths of light at the same point, achieving instant color correction in one extremely thin, miniaturized device. Left to right: Francesco Aieta, Federico Capasso, and Patrice Genevet. Not pictured, Mikhail Kats. (File photo by Eliza Grinnell, Harvard SEAS.)

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