| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 121 | DISPLAY DEVICE | EP12741513 | 2012-01-12 | EP2672312A4 | 2014-09-03 | SUZUKI TOSHIAKI |
| 122 | ACTIVE MATRIX SUBSTRATE AND METHOD FOR MANUFACTURING SAME | EP10840739 | 2010-12-07 | EP2521180A4 | 2014-06-25 | KATSUI HIROMITSU; NAKAMURA WATARU |
| 123 | ELECTRO-OPTIC DEVICE WITH GAP-COUPLED ELECTRODE | EP11836901 | 2011-10-21 | EP2633362A4 | 2014-03-19 | DERI ROBERT J; RHODES MARK A; BAYRAMIAN ANDREW J; CAIRD JOHN A; HENESIAN MARK A; EBBERS CHRISTOPHER A |
| An electro-optic device includes an electro-optic crystal having a predetermined thickness, a first face and a second face. The electro-optic device also includes a first electrode substrate disposed opposing the first face. The first electrode substrate includes a first substrate material having a first thickness and a first electrode coating coupled to the first substrate material. The electro-optic device further includes a second electrode substrate disposed opposing the second face. The second electrode substrate includes a second substrate material having a second thickness and a second electrode coating coupled to the second substrate material. The electro-optic device additionally includes a voltage source electrically coupled to the first electrode coating and the second electrode coating. | ||||||
| 124 | Backlight unit and image display apparatus having the same | EP12199815.7 | 2012-12-31 | EP2645159A1 | 2013-10-02 | Hur, Gil-tae; Jang, Nae-won; Kim, Young-chul; Cho, Kun-ho; Choi, Hyeong-sik |
A backlight unit (50,50'') includes a light guiding plate (70); a light source module (80) that is disposed in at least one side of the light guiding plate and includes a plurality of light sources (81) emitting light toward a side surface (71) of the light guiding plate; an under chassis (60) supporting the light guiding plate and the light source module; and a gap maintaining unit (90;94,95,96) maintaining a gap of a constant width between the side surface of the light guiding plate and the plurality of light sources of the light source module when a length of the light guiding plate is changed.
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| 125 | BIAS CONTROLLER | EP08855951.3 | 2008-11-19 | EP2227715B1 | 2013-09-04 | SMITH, Andrew James; NAWAZ, Mohammed |
| 126 | ACTIVE MATRIX SUBSTRATE AND METHOD FOR MANUFACTURING SAME | EP10840739.6 | 2010-12-07 | EP2521180A1 | 2012-11-07 | KATSUI, Hiromitsu; NAKAMURA, Wataru |
An active matrix substrate includes a plurality of scanning lines (11a) extending parallel to each other; a plurality of signal lines (16a) extending parallel to each other in a direction crossing the scanning lines (11a); a plurality of TFTs (5) each provided at each of intersections of the scanning lines (11 a) and the signal lines (16a), and each including a semiconductor layer (4a) and a source electrode (16aa) and a drain electrode (16b) which are formed on the semiconductor layer (4a) in a layer in which the signal lines (16a) are formed; and a coating type insulating layer formed between each of the scanning lines (11a) and each of the signal lines (16a). A plurality of openings (15a) are formed in the insulating layer such that each of the semiconductor layers (4a) is exposed, and at least part of a peripheral end of the opening (15a) of the insulating layer is positioned on an inner side relative to each of peripheral ends of the semiconductor layers (4a). |
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| 127 | LIQUID CRYSTAL DISPLAY DEVICE | EP10780434.6 | 2010-05-17 | EP2437104A1 | 2012-04-04 | Kumaki, Takaya |
Provided is a liquid crystal display device wherein transmitted illumination is uniformly performed to a liquid crystal display panel and display light (L) has a desired chromaticity. An illuminating means (19) is provided with a first light emitting element (20) which emits first light (L1) having a first color, and a second light emitting element (21) which emits second light (L2) having a second color. A liquid crystal display panel (18) is illuminated by means of illuminating light (L3) which includes the first light (L1) and the second light (L2). A polarization member (27) reflects the illuminating light (L3). A detecting means detects (28) illuminating light (L4) which has passed through the polarization member (27), and outputs chromaticity data. Based on the chromaticity data, a control means (56) adjusts power to be supplied to the first light emitting element (20) and/or second light emitting element (21). The polarization member (27) is composed of a wire grid polarization plate. |
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| 128 | LIQUID CRYSTAL DISPLAY DEVICE | EP09794257 | 2009-05-21 | EP2312384A4 | 2012-04-04 | MIKUBO KAZUYUKI; HASHIGUCHI TAKEYA; SAKAMOTO HITOSHI |
| 129 | POLYMERIZABLE LIQUID CRYSTAL COMPOUND, POLYMERIZABLE LIQUID CRYSTAL COMPOSITION, AND ALIGNMENT FILM | EP07850471.9 | 2007-12-12 | EP2062882B1 | 2011-09-28 | SAHADE, Daniel Antonio |
| Disclosed is a polymerizable liquid crystal compound represented by the formula [1] below, which enables to obtain a polymer having excellent optical anisotropy, excellent chemical resistance and excellent heat resistance, wherein retardation and transparency are stably maintained even at high temperatures. [1] (In the formula, R represents an organic group represented by the formula [A-1], [B-1], [B-2] or [C-1] below; and n represents an integer of 2-9.) (In the formulae, X represents a hydrogen atom, a halogen atom, a cyano group or an alkoxy group; m represents an integer of 2-10; and p represents an integer of 0-6.) | ||||||
| 130 | LIQUID CRYSTAL DISPLAY DEVICE | EP09794257.7 | 2009-05-21 | EP2312384A1 | 2011-04-20 | MIKUBO, Kazuyuki; HASHIGUCHI, Takeya; SAKAMOTO, Hitoshi |
Provided is a highly reliable liquid crystal display device that prevents the penetration of a flying dust and dirt in the outside air. A liquid crystal display device (1) having a display unit housing case (2) configured to house a light source unit and a display unit, and an electronic component housing case (3) configured to house an electronic component. The liquid crystal display device (1) is tightly closed and externally disposed with heat radiation fins (6a and 6b), |
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| 131 | LIQUID CRYSTAL DISPLAY | EP07746907 | 2007-06-14 | EP2035887A4 | 2011-03-30 | KIM KEE YONG |
| 132 | HEAT DISSIPATION STRUCTURE OF OPTICAL ISOLATOR | EP06843374.7 | 2006-12-20 | EP2056156B1 | 2010-09-29 | OCHI, Yuzo; KUBOMURA, Syoji; FUJII, Masayuki |
| 133 | POLYMERIZABLE LIQUID CRYSTAL COMPOUND, POLYMERIZABLE LIQUID CRYSTAL COMPOSITION, AND ALIGNMENT FILM | EP07850471 | 2007-12-12 | EP2062882A4 | 2010-06-30 | SAHADE DANIEL ANTONIO |
| 134 | WAVELENGTH CONVERSION ELEMENT | EP04718393 | 2004-03-08 | EP1602967A4 | 2008-08-20 | NODA KEN-ICHI; IWAI MAKOTO; YOSHINO TAKASHI |
| The invention relates to a wavelength conversion element using a non-linear optical crystal and has the object of preventing the conversion optical output from the wavelength conversion element from becoming unstable. Wavelength conversion elements (1A, 1B) for converting reference light (A) into light (B) of other wavelength are provided. The elements (1A, 1B) are composed of plate-like bodies of non-linear optical crystal, and comprise wavelength conversion layers (2) each having one main surface (2a) and the other main surface (2b),and support bodies (3, 3A) each joined to one main surface (2a) of the wavelength conversion layer (2). Another support body (3B) may be joined to the other main surface (2b) of the wavelength conversion layer (2). | ||||||
| 135 | DISPLAY ASSEMBLIES AND METHODS OF DISPLAY | EP06806174.6 | 2006-10-11 | EP1949178A2 | 2008-07-30 | CAPPAERT, Bart; SCHROEYERS, Jean-Marc |
| Applications of embodiments include the use of transmissive or transflective display technologies in extreme temperature environments. Specifically, display assemblies and methods using heating and/or active cooling are described. For example, such applications may include the use of display panels, such as LCD panels, having a diagonal dimension of 17 inches or more. | ||||||
| 136 | LIQUID CRYSTAL DISPLAY DEVICE AND BACK-LIGHT DEVICE | EP04747560 | 2004-07-15 | EP1653277A4 | 2008-06-04 | NANBU KOHEI; MORIYASU MITSUHIRO; TANAKA KAZUKO |
| A back-light device having optical sheets (6) and (7) capable of solving a problem with the optical sheets (6) and (7) fitted to a conventional back-light device wherein the optical sheets (6) and (7) tend to cause wrinkles thereon by static electricity generated between the optical sheets (6) and (7) and a difference in extension between the optical sheets (6) and (7) due to a difference in the coefficients of thermal expansion thereof, and a liquid crystal display device. In this back-light device, the first and second optical sheets (6) and (7) have different coefficients of linear expansion in different two directions (first direction, second direction), respectively. and the coefficient of linear expansion of the first optical sheet (6) in the first direction larger than the coefficient of linear expansion thereof in the second direction is approximated to the coefficient of linear expansion, in the first direction, of the second optical sheet (7) disposed adjacent to the first optical sheet (6). | ||||||
| 137 | ATHERMAL FIBER BRAGG GRATING | EP06720607.8 | 2006-02-10 | EP1846787A1 | 2007-10-24 | METHE, Joseph, A.; JIAN, Pey, Schuan; SU, Peiti; WANG, David, W.; TSAI, John, C. |
| An athermal fiber Bragg grating assembly (10). A platform (12) provides two attachment locations and has a first coefficient of thermal expansion. A stick (14) provides two ends (14a-b) and has a second coefficient of thermal expansion. A fiber Bragg grating (16) provides two ends (16a-b) and has effective third coefficient of thermal expansion. One stick end is fixed to one grating end, the other stick end is fixed to one attachment location, and the other grating end is fixed to the other attachment location. The stick has a same cross-section area along its length that is equal to or less than the cross-section area of the grating. And the coefficients and lengths between respective locations and ends are such that the assembly exhibits an effective overall coefficient of thermal expansion approaching zero. | ||||||
| 138 | LIQUID CRYSTAL LUMINOUS QUANTITY ADJUSTER, METHOD FOR DRIVING LIQUID CRYSTAL LUMINOUS QUANTITY ADJUSTER, AND CAMERA COMPRISING LIQUID CRYSTAL LUMINOUS QUANTITY ADJUSTER | EP02805014 | 2002-11-15 | EP1457810A4 | 2007-10-03 | TAKAOKA TOSHIFUMI |
| A liquid crystal luminous quantity adjuster for optimizing the effective power of an acceleration drive pulse to improve the response characteristics of a light transmittance, method for driving this device, and camera comprising this device. This liquid crystal luminous quantity adjuster comprises a drive pulse generating circuit (16) for generating a drive pulse of pulsated voltage, a liquid crystal luminous quantity adjusting section (12) supplied with a drive pulse to vary the light transmittance of a liquid crystal according to the shape of the drive pulse, and a microcomputer (19) for controlling the frequency and duty ratio of the drive pulse. The microcomputer (19) make a drive pulse generating circuit (16) generate the drive pulse consisting of the acceleration drive pulse with a pulse shape of the first frequency and first duty ratio and a dimming drive pulse with a pulse shape of the second duty ratio different from the first duty ratio with the second frequency different from the first frequency. | ||||||
| 139 | WAVELENGTH CONVERSION ELEMENT | EP04718393.4 | 2004-03-08 | EP1602967A1 | 2005-12-07 | Noda, Ken-ichi, c/o NGK Insulators, Ltd.; Iwai, Makoto, c/o NGK Insulators, Ltd.; Yoshino, Takashi, c/o NGK Insulators, Ltd. |
An object of the present invention is to prevent the fluctuation of output power of converted light oscillated from a wavelength converting device using a non-linear optical crystal. Wavelength conversion devices 1A, 1B converting fundamental wave "A" to light "B" of the different wavelength are provided. The devices 1A or 1B has a wavelength converting layer 2 comprising a plate-shaped body of a non-linear optical crystal and a first main face 2a and a second main face 2b, and a supporting body 3 or 3A joined with the first main face 2a of the wavelength converting layer 2. An additional supporting body 3B may be joined with the second main face 2b of the wavelength converting layer 2. |
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| 140 | Thermally controlled optical device module | EP04007641.6 | 2004-03-30 | EP1526401A8 | 2005-07-20 | Oikawa, Yoichi, Fujitsu Network Technologies Ltd.; Aota, Hirofumi, Fujitsu Network Technologies Ltd.; Akimoto, Kazuaki Fujitsu Network Technologies Ltd.; Miyata, Hideyuki, c/o Fujitsu Limited; Nakazawa, Tadao |
An optical device module includes an optical device (202), a soaking unit (12) fixed to one surface of the optical device, a heating/cooling unit (14) fixed to one surface of the soaking unit, a heat-insulating unit (22,24) fixed to one surface of the heating/cooling unit, and a package (20) that houses the optical device, the soaking unit, the heating/cooling unit, and the heat-insulating unit and to which the heat-insulating unit is fixed. The heating/cooling unit heats the optical device using self-generated heat or cools the optical device via the soaking unit. |
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