公开(公告)号：US08818492B2

公开(公告)日：2014-08-26

申请号：US13686291

申请日：2012-11-27

Applicant: Korea Institute of Science and Technology

Inventor： Jae Hun Kim ,  Seok Lee ,  Hyuk Jae Lee ,  Taikjin Lee ,  Sun Ho Kim ,  Seok Hwan Kim ,  Jin Wook Jeoung ,  Ki Ho Park ,  Ju Yeong Oh ,  Deok Ha Woo ,  Chulki Kim

IPC: A61B5/05 ,  A61B3/14

CPC classification number: A61B3/145

Abstract: An apparatus for measuring ganglion cells may include: a light generation unit configured to irradiate a first light signal polarized in a first direction and a second light signal polarized in a second direction perpendicular to the first direction to a subject; a reflected light processing unit configured to generate an amplification signal corresponding to an image of the subject using a first reflection signal, which is the first light signal reflected from the subject, and a second reflection signal, which is the second light signal reflected from the subject; and an image processing unit configured to measure ganglion cells in the subject using the amplification signal. The apparatus may be used to count the number of normal ganglion cells in the retina by measuring a phase difference of two lights polarized in different directions. The apparatus may also be used to monitor the progress of glaucoma.

Abstract translation: 用于测量神经节细胞的装置可以包括：光产生单元，被配置为将与第一方向垂直的第二方向上的沿第一方向偏振的第一光信号和第二光信号偏振到对象; 反射光处理单元，被配置为使用作为从被摄体反射的第一光信号的第一反射信号和从第二反射信号反射的第二反射信号，生成与被摄体的图像相对应的放大信号， 学科; 以及图像处理单元，被配置为使用所述放大信号来测量所述对象中的神经节细胞。 该装置可以通过测量在不同方向上偏振的两个光的相位差来计数视网膜中正常神经节细胞的数量。 该装置还可用于监测青光眼的进展。

公开(公告)号：US20140352784A1

公开(公告)日：2014-12-04

申请号：US14042978

申请日：2013-10-01

Applicant: KOREA INSTITUTE OF SCIENCE AND TECHNOLOGY

Inventor： Jae Hun Kim ,  Seong Chan Jun ,  Ju Yeong Oh ,  Seok Lee ,  Taikjin Lee ,  Deok Ha Woo ,  Sun Ho Kim ,  Chul Ki Kim ,  Juhwan Lim

IPC: H01L31/055 ,  H01L31/18

CPC classification number: H01L31/055 ,  C09K11/02 ,  C09K11/65 ,  C09K11/87 ,  H01L33/502 ,  Y02E10/52

Abstract: A photoluminescence wavelength tunable material may include a composite including a graphene oxide layer and metal nanoparticles attached on the graphene oxide layer. By attaching the metal nanoparticles to the graphene oxide, the photoluminescence wavelength (i.e., the color of emitted light) of the graphene oxide may be tuned while maintaining the structure and physical properties of graphene oxide. The photoluminescence wavelength tunable material may be applied to an energy harvesting device such as a solar cell which exhibits high efficiency with less loss of light.

Abstract translation: 光致发光波长可调谐材料可以包括复合物，其包括石墨烯氧化物层和附着在石墨烯氧化物层上的金属纳米颗粒。 通过将金属纳米颗粒附着到氧化石墨烯上，可以在保持氧化石墨烯的结构和物理性质的同时调节氧化石墨烯的光致发光波长（即发射光的颜色）。 光致发光波长可调谐材料可以应用于诸如太阳能电池的能量收集装置，其以较低的光损失表现出高效率。

公开(公告)号：US09903761B2

公开(公告)日：2018-02-27

申请号：US14281348

申请日：2014-05-19

Applicant: Korea Institute of Science and Technology

Inventor： Jae Hun Kim ,  Hyun Seok Song ,  Seok Lee ,  Sun Ho Kim ,  Taikjin Lee ,  Ju Yeong Oh ,  Jun Hyong Cho ,  Chulki Kim ,  Deok Ha Woo

IPC: G01J3/50 ,  G01J1/42 ,  G01J3/28 ,  H01L51/00 ,  H01L51/42

CPC classification number: G01J3/50 ,  G01J1/42 ,  G01J3/2803 ,  H01L51/0093 ,  H01L51/428 ,  Y10T29/49002

Abstract: A photoreceptor protein-based spectrophotometer may include a field-effect transistor and a photoreceptor protein on the field-effect transistor (FET), the photoreceptor protein exhibiting change in electrical properties by absorbing light and being activated. Since the spectrophotometer can convert the light absorbed by the photoreceptor protein to an electrical signal using the FET, it can mimic human vision by using human photoreceptor proteins. The spectrophotometer can measure the color, intensity, etc. of light of broad wavelength ranges as in human vision. Thus, the spectrophotometer can be applied to the development of artificial vision, etc.

公开(公告)号：US10130254B2

公开(公告)日：2018-11-20

申请号：US15472439

申请日：2017-03-29

Applicant: Korea Institute of Science and Technology

Inventor： Jae Hun Kim ,  Seok Hwan Kim ,  Ju Yeong Oh ,  Byeong Ho Park ,  Hyo Suk Kim ,  Min Ah Seo ,  Chul Ki Kim ,  Taik Jin Lee ,  Deok Ha Woo ,  Seok Lee ,  Young Min Jhon

IPC: A61B3/12 ,  A61B3/10 ,  G02B27/00 ,  G02B27/28 ,  G02B26/06 ,  G02B5/30

Abstract: Provided is a cell-level retinal disease detection apparatus including a light imaging means configured to emit light to an eyeball and a light processing means which receives light reflected by the eyeball and processes and compensates light for an astigmatism aberration thereof which occurs at the eyeball to compensate. Here, the light processing means includes a wavefront sensor which senses the astigmatism aberration of the reflected light which occurs due to the eyeball and a light compensation mirror which compensates the light based on the sensed astigmatism aberration, and compensates for a difference in the astigmatism aberration to detect a disease of a retina of the eyeball.