Abstract: An optical waveguide device of the present invention comprises: an optical waveguide including a plurality of cores configured to emit outgoing light from distal ends thereof; and a light-receiving element including a plurality of photo diodes configured to receive the outgoing light. Respective pitches L1 between adjacent cores are greater than pitches L2 between adjacent photo diodes. At least one photo diode on which only outgoing light of each core is incident is present with respect to each of the cores.

Abstract: An optical waveguide device is provided which is capable of distributing light beams from a light source equally to long and short sides of a rectangular panel and which does not require a high degree of accuracy for alignment between the light source and a core. The optical waveguide device includes the light source provided on an edgewise extending frame part of a rectangular panel, and an optical waveguide provided on the frame part and including the branched core having a common portion closer to the light source, the branched core being divided from the common portion into a first core portion and a second core portion orthogonal to each other. The common portion is disposed at a corner of the frame part. The second core portion has a width greater than the width of the first core portion.

Abstract: An outer shape determination device includes: a mounting base having a rectangular mounting surface for placing an object to be subjected to determination thereon; a longitudinal light-emitting optical waveguide, a longitudinal light-receiving optical waveguide, a transverse light-emitting optical waveguide, and a transverse light-receiving optical waveguide which are provided along the periphery of the mounting surface; a heightwise light-emitting optical waveguide and a heightwise light-receiving optical waveguide which are erected upwardly from the mounting surface; a light source connected to light-emitting cores of the longitudinal, transverse and heightwise light-emitting optical waveguides; a photoelectric conversion element connected to light-receiving cores of the longitudinal, transverse and heightwise light-receiving optical waveguides; and an outer shape calculating means for receiving a light interception signal from the photoelectric conversion element to perform a computation process, thereby c

Abstract: An optical waveguide for a touch panel which eliminates the need for alignment between the optical waveguide and a lens and which achieves the appropriate emission and reception of light beams, to provide a touch panel using the optical waveguide, and to provide a manufacturing method of the optical waveguide for a touch panel. A total distance (L) which is the sum of a distance from the center of curvature of the first lens portion 30 to the light reflecting surface 60 and a distance from the light reflecting surface 60 to the tip of the second lens portion 50, and the radius (R) of curvature of the second lens portion 50 satisfy the following condition (A): (L/3)?0.5<R<(L/3)+0.5??(A) where L in mm, and R in mm.

Abstract: An optical waveguide device of the present invention comprises: an optical waveguide including a plurality of cores configured to emit outgoing light from distal ends thereof; and a light-receiving element including a plurality of photo diodes configured to receive the outgoing light. Respective pitches L1 between adjacent cores are greater than pitches L2 between adjacent photo diodes. At least one photo diode on which only outgoing light of each core is incident is present with respect to each of the cores.

Abstract: In an optical coordinate input apparatus, beams emitted from one light emitting element are simultaneously guided through a plurality of cores provided at a waveguide to edges on Y-side and X-side of light emitting sides of an operational area, a light receiving element group includes light receiving elements corresponding respectively to cores aligned on Y-side of light receiving sides and light receiving elements corresponding respectively to cores aligned on X-side of the light receiving sides of the operational area, a scan is performed on each of the light receiving elements sequentially so as to detect presence or absence of a light shielding signal, and a scan time for the scan of all the light receiving elements included in the light receiving element group is set to be not more than 1 ms.

Abstract: There is provided an organic light emitting diode, wherein in a transparent substrate used therein, the length of a side (upper side) on a transparent electrode layer side is shorter than the length of a side (lower side) on an emission side in a cross section parallel to a short side. Ends of the side (upper side) on the transparent electrode layer side and ends of the side (lower side) on the emission side are connected by straight lines or curved lines. Angles (?,?) formed by side surfaces of the transparent substrate and the side (lower side) on the emission side are larger than 0° and smaller than 90°.

Abstract: An apparatus, an optical touch panel, a waveguide, and a process for producing a double layered waveguide structure are provided. The apparatus includes a waveguide having a plurality of transmission waveguide elements and a plurality of reception waveguide elements; a light source coupled to the waveguide; a light detector coupled to the waveguide; and a reflector, spaced apart from the waveguide, the reflector reflecting light emitted from the plurality of transmission waveguide elements towards the reception waveguide elements. The waveguide includes a substrate, a first cladding layer, a reception waveguide, a second cladding layer, a transmission waveguide, and a third cladding layer. The optical touch panel includes a waveguide section comprising a waveguide; a mirror; a surface emitting laser; and a detector.

Abstract: A main path in an optical waveguide with a light-emitting element has two sides faced to each other: one side has a plurality of branched points and the other side does not have any branched points. A width W of the main path becomes narrower as the main path moves away from a light-emitting element. An angle ? formed by the main path and a light guiding direction in each branched point of each branched path is 0.1° to 2.0°. An angle ? formed by the other side without branched points and the light guiding direction of the main path is 0.3° to 1.7°.

Abstract: An outer shape determination device includes: a mounting base having a rectangular mounting surface for placing an object to be subjected to determination thereon; a longitudinal light-emitting optical waveguide, a longitudinal light-receiving optical waveguide, a transverse light-emitting optical waveguide, and a transverse light-receiving optical waveguide which are provided along the periphery of the mounting surface; a heightwise light-emitting optical waveguide and a heightwise light-receiving optical waveguide which are erected upwardly from the mounting surface; a light source connected to light-emitting cores of the longitudinal, transverse and heightwise light-emitting optical waveguides; a photoelectric conversion element connected to light-receiving cores of the longitudinal, transverse and heightwise light-receiving optical waveguides; and an outer shape calculating means for receiving a light interception signal from the photoelectric conversion element to perform a computation process, thereby c

Abstract: In an optical touch panel of the present invention, at a light-emitting side, there is provided an optical waveguide device, in which a light input end of an optical waveguide laminate laminated by a plurality of optical waveguides is optically coupled to a two-dimensional light-emitting element. At a light-receiving side thereof, there is provided an optical waveguide device, in which a light output end of an optical waveguide laminate laminated by a plurality of optical waveguides is optically coupled to a two-dimensional light-receiving element.

Abstract: A three-dimensional sensor optical waveguide which permits size reduction, and a three-dimensional sensor employing the same. A three-dimensional sensor optical waveguide includes a plurality of frame-shaped optical waveguide members stacked coaxially in a thickness direction, and a measurement space defined by inner spaces of the stacked frame-shaped optical waveguide members. The optical waveguide members each include a light emitting core, a light receiving core and an over-cladding layer covering the cores. The light emitting core has a light output end positioned in one of opposed inner edge portions of each of the frame-shaped optical waveguide members. The light receiving core has a light input end positioned in the other inner edge portion of each of the frame-shaped optical waveguide members.

Abstract: An optical waveguide of the present invention includes a light-absorptive section formed in a recess of a clad. The light-absorptive section prevents unwanted light from traveling through the clad. The light-absorptive section absorbs light at all wavelengths (infrared light, visible light, and ultraviolet light). The light-absorptive section is located adjacent to a light-receiving element. In the case where there is a light-absorptive section, cores are encircled by the thin clad and the thin clad encircling respective cores is encircled by the light-absorptive section.

Abstract: An optical waveguide with photoelectric conversion element includes an under-cladding layer and an over-cladding layer including a thick portion having a large thickness and a thin portion having a small thickness. The optical waveguide with photoelectric conversion element is bendable in a region including the thin portion in such a direction that the under-cladding layer faces inward. This makes it possible to arrange a photoelectric conversion element of each of the optical waveguides with photoelectric conversion element and its associated circuit on the back side of a display panel of an optical touch panel, thereby reducing the size of a frame surrounding a coordinate input region of the optical touch panel and the difference in level on the surface of the frame and its vicinity.

Abstract: An optical waveguide device is provided which is capable of distributing light beams from a light source equally to long and short sides of a rectangular panel and which does not require a high degree of accuracy for alignment between the light source and a core. The optical waveguide device includes the light source provided on an edgewise extending frame part of a rectangular panel, and an optical waveguide provided on the frame part and including the branched core having a common portion closer to the light source, the branched core being divided from the common portion into a first core portion and a second core portion orthogonal to each other. The common portion is disposed at a corner of the frame part. The second core portion has a width greater than the width of the first core portion.

Abstract: There is provided an L-shaped optical waveguide device, wherein a coupled end of a first I-shaped optical waveguide has a concave portion and a coupled end of a second I-shaped optical waveguide has a convex portion. A concave-convex joint is formed by fitting the concave portion with the convex portion to couple the first and second I-shaped optical waveguides to each other. A plurality of cores which belong to the second I-shaped optical waveguide having the convex portion respectively bend approximately at a right angle near a photoelectric conversion element to be optically coupled to the photoelectric conversion element.

Abstract: A transparent electrically-conductive hard-coated substrate of the invention comprises a transparent base material; a deposited carbon nanotubes layer formed on the transparent base material; and a cured resin layer formed on the deposited carbon nanotubes layer, wherein the deposited carbon nanotubes layer has a thickness of 10 nm or less, the total thickness of the deposited carbon nanotubes layer and the cured resin layer is 1.5 ?m or more, and part of the deposited carbon nanotubes layer is diffused into the cured resin layer so that carbon nanotubes are present in the cured resin layer. The transparent electrically-conductive hard-coated substrate possesses high transparency and hard coating properties and also has electrical conductivity.

Abstract: An optical waveguide for a touch panel in which the intensity of light beams emitted from light-emitting portions of a plurality of light-emitting cores in the form of branches is substantially uniform independently of the branch position of the light-emitting cores, and a touch panel using the same. An optical waveguide for a touch panel is provided in which a plurality of light-emitting cores 33 are formed by dividing a tip portion of a single original core into branches. A portion extending from a basal portion 32b of the original core to a branch point 32c at which the division into the branches serving as the light-emitting cores 33 starts is an isosceles triangular portion 32 gradually widened from the basal portion 32b into the shape of an isosceles triangle. The isosceles triangle has a taper angle ? in the range greater than 0 degrees and less than 15 degrees.

Abstract: An optical touch panel 10 has means 20 for generating a signal to provide an operator with input operational feeling. The center of a light-emitting sided-core 17 is positioned lower than the center of a light-emitting sided-optical waveguide 14 and the center of a light-receiving sided-core 19 is positioned lower than the center of a light-receiving sided-optical waveguide 15, thereby light beams 22 are situated close to a transparent panel 21, and this enables to obtain natural input operational feeling having a minimal time lag between input operation and a signal generation to provide input operational feeling.

Abstract: A touch panel 30 of the present invention comprises: a light-emitting sided-optical waveguide 33; a light-receiving sided-optical waveguide 34; and an electromagnetic induction-type digitizer 36. In the touch panel of the present invention, a position coordinate is recognized using an electronic pen by an electromagnetic induction-type digitizer 36 when high resolution is required. A position coordinate is recognized using a finger by the optical waveguides 33 and 34 when high resolution is not required. This makes it possible to materialize the touch panel 30 having a high resolution and a lower power consumption regardless of its narrow frame.