| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 1 | 液晶光栅及其制作方法、显示装置 | CN201410784528.2 | 2014-12-16 | CN104460132A | 2015-03-25 | 陈玉琼 |
| 本发明实施例公开了一种液晶光栅及其制作方法、显示装置,涉及显示技术领域,可以改善黑色条纹现象。该液晶光栅包括相对设置的第一基板、第二基板以及液晶分子层,第一基板上设有板状透明电极,第二基板上依次设有第二透明导电层、透明绝缘层和第一透明导电层;第一透明导电层包括相互间隔设置的第一条状透明电极和第二条状透明电极,相邻的第一条状透明电极和第二条状透明电极之间具有间隙;第二透明导电层包括间隔设置的第三条状透明电极;第二条状透明电极的电压以及第三条状透明电极的电压与板状透明电极的电压相同,且与第一条状透明电极的电压不同。 | ||||||
| 2 | 双层交叉式P-N二极管调制器 | CN201380027000.4 | 2013-04-16 | CN104321849A | 2015-01-28 | W·M·格林; J·C·罗森伯格; Y·A·弗拉索夫 |
| 一种用于制造光调制器的方法包括:形成n型层,所述n型层的一部分上的第一氧化物部、以及所述n型层的第二部分上的第二氧化物部;在所述第一氧化物部、所述n型层的平面表面的部分、以及所述第二氧化物部的部分之上图案化第一掩蔽层;在所述n型层中注入p型掺杂剂以形成第一p型区和第二p型区;去除所述第一掩蔽层;在所述第一氧化物部、所述第一p型区的一部分、以及所述n型层的一部分之上图案化第二掩蔽层;以及在所述n型层的暴露部、所述第一p型区的暴露部、以及被设置在所述衬底与所述第二氧化物部之间的所述n型层和所述第二p型区的区域中注入p型掺杂剂。 | ||||||
| 3 | 电光器件 | CN02825923.8 | 2002-11-19 | CN100394255C | 2008-06-11 | 帕维尔·I·拉扎列夫; 迈克尔·V·保克什托; 弗拉迪米尔·苏利莫夫 |
| 提供一种电光器件,其包括至少一个衬底(1),至少一对电极(2)以及至少一层电光材料。该电光材料代表光学各向异性薄晶体薄膜(3),并且包含具有芳香环且具有沿着光轴之一、面间距(布喇格反射)为3.4±0.2的晶格的分子。电光材料(3)具有依赖于电场强度的各向异性折射率和/或各向异性吸收系数。 | ||||||
| 4 | 双层交叉式P-N二极管调制器 | CN201380027000.4 | 2013-04-16 | CN104321849B | 2017-02-08 | W·M·格林; J·C·罗森伯格; Y·A·弗拉索夫 |
| 一种用于制造光调制器的方法包括:形成n型层,所述n型层的一部分上的第一氧化物部、以及所述n型层的第二部分上的第二氧化物部;在所述第一氧化物部、所述n型层的平面表面的部分、以及所述第二氧化物部的部分之上图案化第一掩蔽层;在所述n型层中注入p型掺杂剂以形成第一p型区和第二p型区;去除所述第一掩蔽层;在所述第一氧化物部、所述第一p型区的一部分、以及所述n型层的一部分之上图案化第二掩蔽层;以及在所述n型层的暴露部、所述第一p型区的暴露部、以及被设置在所述衬底与所述第二氧化物部之间的所述n型层和所述第二p型区的区域中注入p型掺杂剂。 | ||||||
| 5 | 液晶显示装置 | CN200580026384.3 | 2005-05-20 | CN1993727B | 2010-06-02 | 伊藤高幸; 河内浩康; 竹内范仁; 原田昌幸; 三浦裕之; 石川明幸; 户枝稔; 吉田干雄; 别芝范之; 小池秀儿 |
| 液晶显示装置具有液晶面板和照明装置。照明装置由EL元件构成面状的发光区域。发光区域由在与液晶的垂直扫描方向正交的方向上延伸的多个线状发光区域构成。根据来自控制装置的指令信号将多个线状发光区域切换为发光状态与非发光状态,以使与液晶的垂直扫描同步地依次进行发光。控制线状发光区域,以使至少在位于该线状发光区域正上方的液晶的部分的驱动数据改写期间成为非发光状态。 | ||||||
| 6 | 液晶显示装置 | CN200580026384.3 | 2005-05-20 | CN1993727A | 2007-07-04 | 伊藤高幸; 河内浩康; 竹内范仁; 原田昌幸; 三浦裕之; 石川明幸; 户枝稔; 吉田干雄; 别芝范之; 小池秀儿 |
| 液晶显示装置具有液晶面板和照明装置。照明装置由EL元件构成面状的发光区域。发光区域由在与液晶的垂直扫描方向正交的方向上延伸的多个线状发光区域构成。根据来自控制装置的指令信号将多个线状发光区域切换为发光状态与非发光状态,以使与液晶的垂直扫描同步地依次进行发光。控制线状发光区域,以使至少在位于该线状发光区域正上方的液晶的部分的驱动数据改写期间成为非发光状态。 | ||||||
| 7 | 光学元件以及极化反转区域的形成方法 | CN200580003045.3 | 2005-03-15 | CN1910512A | 2007-02-07 | 森川显洋; 杉田知也; 水内公典 |
| 本发明提供一种在强电介质晶体中,具有均匀且大范围的细微极化反转构造的稳定的光学元件。具有形成在MgO:LiNbO3基板(100)中的多个极化反转部(101);以及形成在极化反转部(101)之间的基板表面上的沟(102),极化反转部(101)的几乎全体的深度T’相对基板厚度T,满足T’<T的关系。 | ||||||
| 8 | 液晶光栅及其制作方法、显示装置 | CN201410784528.2 | 2014-12-16 | CN104460132B | 2017-11-07 | 陈玉琼 |
| 本发明实施例公开了一种液晶光栅及其制作方法、显示装置,涉及显示技术领域,可以改善黑色条纹现象。该液晶光栅包括相对设置的第一基板、第二基板以及液晶分子层,第一基板上设有板状透明电极,第二基板上依次设有第二透明导电层、透明绝缘层和第一透明导电层;第一透明导电层包括相互间隔设置的第一条状透明电极和第二条状透明电极,相邻的第一条状透明电极和第二条状透明电极之间具有间隙;第二透明导电层包括间隔设置的第三条状透明电极;第二条状透明电极的电压以及第三条状透明电极的电压与板状透明电极的电压相同,且与第一条状透明电极的电压不同。 | ||||||
| 9 | TFT-LCD的阵列基板及其制造方法 | CN201010611650.1 | 2010-12-28 | CN102566155B | 2014-07-02 | 孙荣阁; 叶* |
| 本发明实施例公开了一种TFT-LCD的阵列基板及其制造方法,涉及液晶显示器技术领域,能够在对位精度不高时,减小存储电容。该阵列基板包括:基板,基板上的栅线和数据线;栅线和数据线交叉定义一个像素单元,每一个像素单元包括薄膜晶体管、公共电极、通过绝缘层隔开的第一像素电极层和第二像素电极层;第一像素电极层与公共电极连接,包括被第一像素电极层开口间隔开的数个第一像素电极;第二像素电极层与薄膜晶体管的漏极连接,包括被第二像素电极层开口间隔开的数个第二像素电极;第二像素电极包括完全重叠于第一像素电极的重叠处像素电极和其边缘完全落入第一像素电极层开口内的开口处像素电极。 | ||||||
| 10 | TFT-LCD的阵列基板及其制造方法 | CN201010611650.1 | 2010-12-28 | CN102566155A | 2012-07-11 | 孙荣阁; 叶* |
| 本发明实施例公开了一种TFT-LCD的阵列基板及其制造方法,涉及液晶显示器技术领域,能够在对位精度不高时,减小存储电容。该阵列基板包括:基板,基板上的栅线和数据线;栅线和数据线交叉定义一个像素单元,每一个像素单元包括薄膜晶体管、公共电极、通过绝缘层隔开的第一像素电极层和第二像素电极层;第一像素电极层与公共电极连接,包括被第一像素电极层开口间隔开的数个第一像素电极;第二像素电极层与薄膜晶体管的漏极连接,包括被第二像素电极层开口间隔开的数个第二像素电极;第二像素电极包括完全重叠于第一像素电极的重叠处像素电极和其边缘完全落入第一像素电极层开口内的开口处像素电极。 | ||||||
| 11 | 电光器件,电光薄晶体薄膜及其制造方法 | CN02825923.8 | 2002-11-19 | CN1672086A | 2005-09-21 | 帕维尔·I·拉扎列夫; 迈克尔·V·保克什托; 弗拉迪米尔·苏利莫夫 |
| 提供一种电光器件,其包括至少一个衬底(1),至少一对电极(2)以及至少一层电光材料。该电光材料代表光学各向异性薄晶体薄膜(3),并且包含具有芳香环且具有沿着光轴之一、面间距(布喇格反射)为3.4±0.2的晶格的分子。电光材料(3)具有依赖于电场强度的各向异性折射率和/或各向异性吸收系数。 | ||||||
| 12 | The method of forming the optical element as well as the polarization inversion region | JP2006511189 | 2005-03-15 | JP4926700B2 | 2012-05-09 | 知也 杉田; 顕洋 森川; 公典 水内 |
| 13 | Manufacture of optical waveguide | JP2000570620 | 1999-09-14 | JP4579417B2 | 2010-11-10 | ガウイズ,コリン・バーリイ・エドモンド; シエプフエルド,デイビツト・ピー; スミス,ピーター・ジヨージ・ロビン; ハンナ,デイビツド・コリン; ロス,グレーム・ウイリアム |
| 14 | Phase shifter and electro-optic modulation device including the same | US13239936 | 2011-09-22 | US08634678B2 | 2014-01-21 | Kwang-Hyun Lee; Dong-Jae Shin; Kyoung-Ho Ha |
| A phase shifter includes an optical waveguide, a plurality of impurity regions and a plurality of electrodes. The optical waveguide receives an optical input signal and outputs an optical output signal. The impurity regions include respective charge carriers. The impurity regions are disposed in contact with the optical waveguide at respective contact surface, where at least one of the contact surfaces has a zigzag pattern. The electrodes are connected to the respective impurity regions. Application of an electrical signal to at least one of the electrodes phase-shifts the optical output signal with respect to the optical input signal. Therefore, the phase shifter may efficiently vary a magnitude of the phase shift of the optical output signal. | ||||||
| 15 | System for generating Raman vibrational analysis signals | US13055878 | 2009-07-29 | US08446580B2 | 2013-05-21 | Giulio Nicola Felice Cerullo; Marco Andrea Arrigo Marangoni; Fabio Baronio; Matteo Conforti; Costantino De Angelis |
| A system for generating signals for Raman vibrational analysis, particularly for a CARS microscope or spectroscope of an external specimen, the system including a laser source capable of emitting at least one fundamental optical pulse in a first band of fundamental frequencies including at least one first and one second fundamental frequencies; a second-harmonic generating system including at least one nonlinear optical crystal for converting the at least one fundamental optical pulse into a first and a second-harmonic optical pulse; and a Raman vibrational analysis apparatus capable of receiving the first and second second-harmonic pulses and direct them toward the specimen. | ||||||
| 16 | Distributed aperture head-up display | US11303290 | 2005-12-16 | US08228358B2 | 2012-07-24 | Brent D. Larson; Elias S. Haim; Matthew B. Dubin |
| Method and apparatus are provided for displaying an image to a viewer with reduced visual artifacts. The apparatus comprises a display panel for forming the image using an array of pixels with distributed active regions, and a viewing arrangement optically situated between the display panel and the viewer for transferring the image formed on the display panel to the viewer with limited angular pixel subtense. The distributed active regions of the pixels are desirably divided into at least two simultaneously switched portions at least partly separated by or surrounding a significant portion of the non-switchable region. First order spatial harmonics and associated artifacts are reduced by the distributed apertures and second order and higher harmonics are reduced by limiting the pixel subtense angle seen by the viewer. A significant reduction in visual artifacts arising from the periodic structure of the display panel is obtained. | ||||||
| 17 | System for Generating Raman Vibrational Analysis Signals | US13055878 | 2009-07-29 | US20110128538A1 | 2011-06-02 | Giulio Nicola Felice Cerullo; Marco Andrea Arrigo Marangoni; Fabio Baronio; Matteo Conforti; Costantino De Angelis |
| A system for generating signals for Raman vibrational analysis, particularly for a CARS microscope or spectroscope of an external specimen, the system comprising a a laser source apt to emit at least one fundamental optical pulse in a first band of fundamental frequencies comprising at least one first (ωf1) and one second (ωf2) fundamental frequencies; a second-harmonic (SH) generating system comprising at least one nonlinear optical crystal for converting said at least one fundamental optical pulse into at least two second-harmonic optical pulses, i.e. a first second-harmonic pulse at a first second-harmonic frequency (ωp) of the first fundamental frequency (ωf1) and a second second-harmonic pulse at a second second-harmonic frequency (ωs) of the second fundamental frequency (ωf2), said second second-harmonic frequency being other than the first second-harmonic frequency, and a Raman vibrational analysis apparatus apt to receive said first and second second-harmonic pulses and direct them toward said specimen.According to an embodiment, the SH system comprises two nonlinear optical crystals, each including a ferroelectric crystal with periodic space-modulation of the sign of the optical susceptibility.In a different embodiment, the SH system comprises a ferroelectric crystal with aperiodic space-modulation of the sign of nonlinear optical susceptibility, with a period varying along the optical path of said at least one fundamental optical pulse, said crystal being apt to generate said first and second second-harmonic pulses. | ||||||
| 18 | Liquid Crystal Display Device | US11659569 | 2005-05-20 | US20080309593A1 | 2008-12-18 | Takayuki Ito; Hiroyasu Kawauchi; Norihito Takeuchi; Masayuki Harada; Hiroyuki Miura; Haruyuki Ishikawa; Minoru Toeda; Mikio Yoshida; Noriyuki Besshi; Shuji Koike |
| A liquid crystal display device includes a liquid crystal panel and an illumination unit. The illumination unit has a planar light emitting region formed by an EL element. The light emitting region is formed by a plurality of linear light emitting regions that extend in a direction perpendicular to the vertical scanning direction of liquid crystal. The linear light emitting regions are switched between a light emitting state and a non-light emitting state based on a command signal from a controller in a manner that the linear light emitting regions sequentially emit light in synchronization with vertical scanning of the liquid crystal. Each linear light emitting region is controlled to be in the non-light emitting state at least during a drive data rewriting period of a portion of the liquid crystal immediately above the linear light emitting region. | ||||||
| 19 | Distributed aperture head-up display | US11303290 | 2005-12-16 | US20060139503A1 | 2006-06-29 | Brent Larson; Elias Haim; Matthew Dubin |
| Method and apparatus are provided for displaying an image to a viewer with reduced visual artifacts. The apparatus comprises a display panel for forming the image using an array of pixels with distributed active regions, and a viewing arrangement optically situated between the display panel and the viewer for transferring the image formed on the display panel to the viewer with limited angular pixel subtense. The distributed active regions of the pixels are desirably divided into at least two simultaneously switched portions at least partly separated by or surrounding a significant portion of the non-switchable region. First order spatial harmonics and associated artifacts are reduced by the distributed apertures and second order and higher harmonics are reduced by limiting the pixel subtense angle seen by the viewer. A significant reduction in visual artifacts arising from the periodic structure of the display panel is obtained. | ||||||
| 20 | Optical waveguide and fabrication method | US09762805 | 2001-02-13 | US06834151B1 | 2004-12-21 | Peter G R Smith; Graeme W Ross; David C Hanna; David P Shepherd; Corin B E Gawith |
| An optical waveguide with at least a guiding lamina (10) of optical material bonded by direct interfacial bonding to a superstructure lamina (20) of optical material, in which regions of the guiding lamina have modified optical properties so as to define a light guiding path along the guiding lamina. In a particular example, a periodically poled LiNbO3 planar waveguide is buried in LiTaO3 by direct interfacial bonding and precision polishing techniques and used in an optical frequency doubling system. | ||||||
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