Patent application number | Description | Published |
20080221341 | Trisoxetane compound, process for producing the same, and opitcal waveguide using the same - The present invention relates to a trisoxetane compound represented by the following formula (1): | 09-11-2008 |
20090261488 | MANUFACTURING METHOD OF OPTICAL WAVEGUIDE MODULE - A manufacturing method of an optical waveguide module which is capable of forming a light reflecting portion with stabilized accuracy and which is good in production efficiency. The manufacturing method of an optical waveguide module in which an optical element is mounted on the back side of end portions of an optical waveguide is provided. For the production of the above-mentioned optical waveguide, end portions of an over cladding layer | 10-22-2009 |
20090286187 | MANUFACTURING METHOD OF OPTICAL WAVEGUIDE DEVICE - To provide a manufacturing method of an optical waveguide device which is capable of suppressing the surface roughening of core side surfaces of an optical waveguide when the optical waveguide is formed on a surface of a metal substrate. An under cladding layer | 11-19-2009 |
20090305170 | OPTICAL WAVEGUIDE MANUFACTURING METHOD - An optical waveguide manufacturing method which obviates a developing step and stably provides greater differences in refractive index between a core and cladding layers. A core formation photosensitive resin layer is formed on a surface of an under-cladding layer, and then exposed in a predetermined pattern. A core is formed which is defined by an exposed portion of the core formation photosensitive resin layer. Surfaces of the exposed portion and an unexposed portion of the core formation photosensitive resin layer are covered with an over-cladding layer formation photosensitive resin layer. The two photosensitive resin layers are heated, whereby a resin of the unexposed portion of the core formation photosensitive resin layer and a resin of the over-cladding layer formation photosensitive resin layer are melt-mixed together to form a mixture layer. Then, the mixture layer is exposed, whereby a third cladding layer is formed defined by the exposed mixture layer. | 12-10-2009 |
20100008621 | MANUFACTURING METHOD OF OPTO-ELECTRIC HYBRID BOARD AND OPTO-ELECTRIC HYBRID BOARD OBTAINED THEREBY - A method of manufacturing an opto-electric hybrid board which is capable of reducing the number of steps for the manufacture of the opto-electric hybrid board and which achieves the reduction in thickness of the opto-electric hybrid board to be manufactured, and an opto-electric hybrid board obtained thereby. A plurality of protruding cores (optical interconnect lines) | 01-14-2010 |
20100019401 | METHOD FOR MANUFACTURING OPTICAL WAVEGUIDE - A resin layer | 01-28-2010 |
20100033445 | OPTICAL TOUCH PANEL - An optical touch panel | 02-11-2010 |
20100034501 | COMBINED STRUCTURE OF OPTICAL WAVEGUIDE - A combined structure of optical waveguides with high accuracy can be easily materialized by arranging cutout sections | 02-11-2010 |
20100067849 | MANUFACTURING METHOD OF OPTICAL WAVEGUIDE DEVICE AND OPTICAL WAVEGUIDE DEVICE OBTAINED THEREBY - A manufacturing method of an optical waveguide device and an optical waveguide device obtained thereby. An under cladding layer is formed on the front surface of a colored-layer-coated PET substrate including a PET substrate portion and a colored layer of a color that absorbs irradiation light and formed on the back surface of the PET substrate portion, and then a photosensitive resin layer for the formation of cores is formed thereon. In forming the cores, when the irradiation light reaches the bottom surface of the PET substrate portion, most of the irradiation light is absorbed by the colored layer, so that there is little irradiation light reflected from the bottom surface of the PET substrate portion. This significantly reduces the irradiation light reflected diffusely from the PET substrate portion and reaching the photosensitive resin layer to thereby effectively suppress the surface roughening of the side surfaces of the cores. | 03-18-2010 |
20100068653 | MANUFACTURING METHOD OF OPTICAL WAVEGUIDE DEVICE - A manufacturing method of an optical waveguide device which is capable of suppressing the surface roughening of core side surfaces of an optical waveguide when the optical waveguide is formed on a roughened surface of a substrate. An under cladding layer is formed on a roughened surface of a substrate made of a material that absorbs irradiation light, and then a photosensitive resin layer for the formation of cores is formed thereon. Irradiation light is directed toward this photosensitive resin layer to expose the photosensitive resin layer in a predetermined pattern to the irradiation light. When the irradiation light transmitted through the photosensitive resin layer for the formation of the cores and the under cladding layer reaches the surface of the substrate, the irradiation light is absorbed by the substrate, so that there is little irradiation light reflected from the surface of the substrate. | 03-18-2010 |
20100092893 | METHOD OF MANUFACTURING OPTICAL WAVEGUIDE DEVICE - A method of manufacturing an optical waveguide device capable of suppressing the surface roughening of core side surfaces of an optical waveguide. Forming an under cladding layer on the front surface of a substrate; forming a photosensitive resin layer for core formation on a surface of the under cladding layer; wherein, in forming the cores, (A) irradiation light transmitted through the photosensitive resin layer, reaching the front surface of the substrate having an arithmetic mean roughness (Ra) in the range of 1 to 2 nm, or (B) irradiation light transmitted through the photosensitive resin layer and reflected from the bottom surface, where the front surface and back surface both have an arithmetic mean roughness (Ra) in the range of 1 to 2 nm. | 04-15-2010 |
20100188367 | OPTICAL WAVEGUIDE WITH LIGHT EMITTING DEVICE AND OPTICAL TOUCH PANEL - In an optical waveguide | 07-29-2010 |
20120134630 | OPTICAL CONNECTOR AND METHOD OF MANUFACTURING SAME - An optical connector reduced in size and capable of reducing optical coupling losses when optical waveguides are connected to each other, and a method of manufacturing the same are provided. The optical connector comprises: an optical waveguide including cores for transmitting light, an under cladding layer provided under the cores, and an over cladding layer provided over the cores; and a ferrule section for optical connection provided in each end portion of the optical waveguide. Part of at least one of the over cladding layer and the under cladding layer lying in a location corresponding to each end portion of the optical waveguide is thick-walled to become the ferrule section for optical connection. A thin-walled part of the optical connector lying between the ferrule sections is an optical waveguide section. The optical connector requires no additional component as a ferrule, and is made small in size. | 05-31-2012 |
20120201490 | OPTICAL SENSOR MODULE - An optical sensor module is provided in which an engagement portion of a board unit is fitted in a groove of an optical waveguide unit and, even with the single engagement portion, the board unit is stably supported. An optical sensor module includes an optical waveguide unit, and a board unit mounted with an optical element and coupled to the optical waveguide unit. The optical waveguide unit includes a single edge extension portion axially extending along one side edge of an over-cladding layer, a board unit engagement groove provided in the single edge extension portion, and a projection provided on a side wall of the vertical groove and kept in abutment against an engagement portion of the board unit. The board unit includes an engagement portion fitted in the vertical groove, which abuts against the projection within the vertical groove. | 08-09-2012 |
20120306818 | SMALL-SIZED INPUT DEVICE - A small-sized input device is provided which includes: a rectangular frame-shaped optical waveguide having a rectangular hollow input-use interior that is not more than 10 cm in length and not more than 10 cm in width; and a control means provided on the outside of one of the sides of the optical waveguide. The optical waveguide and the control means are provided on the front surface of a rectangular frame-shaped retainer plate having the hollow input-use interior, and are covered with a rectangular frame-shaped protective plate. The control means includes: a light-emitting element connected to ends of light-emitting cores of the optical waveguide; a light-receiving element connected to ends of light-receiving cores of the optical waveguide; and an optical sensor for recognizing the amount (or distance) of movement of the small-sized input device. | 12-06-2012 |
20120327033 | INPUT DEVICE - An input device which allows a user to erase display information such as a character inputted thereto is provided. The input device includes a rectangular frame-shaped optical waveguide having a rectangular hollow input-use interior, and a control means provided on the outside of one of the sides of the optical waveguide. The optical waveguide and the control means are provided on a surface of a rectangular frame-shaped retainer plate having the hollow input-use interior, and are covered with a rectangular frame-shaped protective plate. The control means includes: a light-emitting element connected to ends of light-emitting cores of the optical waveguide; a light-receiving element connected to ends of light-receiving cores of the optical waveguide; and a CPU incorporating a program for recognizing the size of the tip of a pen and the size of the tip of an eraser in a region within the hollow input-use interior. | 12-27-2012 |
20130048834 | INPUT DEVICE - The input device includes a frame-shaped optical waveguide having a hollow input-use interior, and a control means provided on the outside of one of the sides of the optical waveguide. The optical waveguide and the control means are provided on a surface of a frame-shaped retainer plate. The control means includes: a light-emitting element connected to ends of light-emitting cores of the optical waveguide; a light-receiving element connected to ends of light-receiving cores of the optical waveguide; and a CPU incorporating a program. Upon sensing a first light-shielded area where light is intercepted by the tip of a pen and a second light-shielded area where light is intercepted by user's hand that holds the pen, the program recognizes the second light-shielded area larger than the first light-shielded area as unnecessary information, based on a difference in light-shielded area. | 02-28-2013 |
20130087691 | INPUT DEVICE - An input device capable of lowering the vertical position of light beams traveling within the frame of a frame-shaped optical waveguide without using optical path conversion is provided. The input device includes a light-emitting module incorporating a light-emitting element connected to light-emitting cores of the optical waveguide, and a light-receiving module incorporating a light-receiving element connected to light-receiving cores of the optical waveguide. A section of the optical waveguide on a light-receiving side, in which the light-receiving cores are formed, is placed upside down so that an over cladding layer is positioned on the underside. Accordingly, the light-receiving module is also placed upside down. Thus, the light-receiving module protrudes along the height thereof in such a manner that the amount of downward protrusion is less than the amount of upward protrusion. | 04-11-2013 |
20150035802 | ELECTRONIC UNDERLAY WITH WIRELESS TRANSMISSION FUNCTION - Provided is an electronic underlay with a wireless transmission function, designed not to sense a hand holding a writing tool at the time of writing on a sheet. The electronic underlay with a wireless transmission function can be laid under a sheet to perform writing with a writing tool. The electronic underlay is provided with: a sheet-like optical waveguide formed by sandwiching lattice-like cores between a sheet-like under cladding layer and a sheet-like over cladding layer; a light emitting element connected to one end surface of the core; a light receiving element connected to another end surface of the core; and wireless transmission means for wirelessly transmitting inputted letters as electronic data. An elasticity modulus of the core is larger than an elasticity modulus of the under cladding layer and the over cladding layer. | 02-05-2015 |