Abstract: A laser processing apparatus that condenses a laser beam into an annular shape to irradiate the condensing position of the laser beam within a thickness range of a substrate, and shifts the condensing position in such a manner that the center of the condensing position that is annular moves in a circular manner, at a stage of shifting the condensing position in a thickness direction of the substrate and a planar direction of the substrate.

Abstract: The present invention relates to a method for producing a deposition mask having a structure in which a metal mask sheet with a plurality of opening patterns formed is disposed under tension on and fixed to a metal frame, the method including: a first step of bonding a peripheral part of the metal mask sheet to a synthetic fiber mesh to which constant tension is applied; a second step of cutting off a part of the mesh corresponding to a deposition effective region with a size capable of arranging therein the plurality of opening patterns of the metal mask sheet; a third step of connecting and fixing the frame to the peripheral part of the metal mask sheet on an opposite side to the mesh; and a fourth step of removing the mesh from the metal mask sheet.

Abstract: Signal transmission crosstalk between substrates is suppressed even when light emitting elements or light receiving elements are densely arranged. Provided is an optical interconnection device 1 in which optical signals are sent and received between a plurality of semiconductor substrates arranged in a laminated manner. A light emitting element 2 or a light receiving element 3 arranged in one semiconductor substrate 10 includes a pn junction part 10pn that uses the semiconductor substrate 10 as a common semiconductor layer, and is formed on one surface side of the semiconductor substrate 10. For a pair of the light emitting element 2 and the light receiving element 3 respectively sending and receiving optical signals between the different semiconductor substrates 10, light emitted by the light emitting element 2 is transmitted through the semiconductor substrate 10 and received by the light receiving element 3.

Abstract: When a visible light image and an image of a long-wavelength region with a near-infrared wavelength or longer are acquired using one imaging sensor, a clear image of the long-wavelength region with the near-infrared wavelength or longer is obtained. In an imaging sensor 1 in an imaging device, a plurality of photoelectric conversion parts 2 (2A, 2B) are formed on one semiconductor substrate 10. The respective photoelectric conversion parts 2A in a group of the plurality of photoelectric conversion parts 2 (2A, 2B) exhibit spectral sensitivity characteristics that peak in a long-wavelength region with a near-infrared wavelength or longer. The plurality of photoelectric conversion parts 2 (2A, 2B) include photoelectric conversion parts 2B exhibiting spectral sensitivity characteristics that peak in a visible light region.

Abstract: The semiconductor optical integrated circuit has a semiconductor substrate; a pn junction part formed in the semiconductor substrate so as to continuously extend along a signal transmission route, a light emitting part formed on a part of the pn junction part; and an optical waveguide part formed continuous to the light emitting part on the pn junction part. The light emitting part supplies a drive current to the pn junction part to generate an optical signal from the pn junction part, and the optical waveguide part transmits the optical signal while amplifying the optical signal by an amplification current supplied to the pn junction part.

Abstract: A method including: a first step of forming a mask member having a structure in which a magnetic metal member provided with through-holes is in tight contact with one surface of a film; a second step of forming a plurality of preliminary opening patterns by subjecting the film to penetration processing by irradiating laser beams at predetermined regular positions in the plurality of through-holes; and a third step of performing laser processing so as to form each opening pattern over the corresponding preliminary opening pattern, is provided.

Abstract: The deposition mask includes: a thin plate-shaped magnetic metal member 1 in which a through-hole 4 having shape and dimensions greater than those of the thin-film pattern is provided at a position corresponding to the thin-film pattern; and a resin film 2 which is provided in close contact with one surface of the magnetic metal member 1 and in which an opening pattern 5 having shape and dimensions identical to those of the thin-film pattern is formed at a position corresponding to the thin-film pattern in the through-hole 4, the resin film 2 being permeable to visible light. The opening pattern 5 is provided within an opening pattern formation region 7 surrounded by a deposition shadow region 6 defined by the thickness of the magnetic metal member 1 and the maximum angle of incidence of the deposition material to the film surface in the through-hole 4.

Abstract: A deposition mask for forming a thin film pattern having a predetermined shape on a substrate by deposition, includes a resin film that transmits visible light and has an opening pattern penetrating through the resin film and having the same shape and dimension as those of the thin film pattern so as to correspond to a preliminarily determined forming region of the thin film pattern on the substrate.

Abstract: A microlens array is a stacked body of four unit microlens arrays, and the optical axis of a portion of the unit microlens arrays can be shifted from the optical axis of the other unit microlens arrays. In a scanning exposure apparatus, a CCD line camera detects an image on a substrate, and using a first-layer pattern on the substrate as a reference pattern, in a case in which a mask exposure pattern does not match the reference pattern, shifts the optical axis of the microlenses to adjust the magnification of a projection pattern using the microlens array. This makes it possible to adjust the exposure position using the microlens array so that even when the exposure pattern deviates from the reference pattern, the deviation can be detected during exposure and an exposure pattern misregistration can be prevented, enabling the precision of the exposure pattern to be enhanced in an overlay exposure.

Abstract: In the present invention, At least one row of lens arrays, in which a plurality of lenses are arranged in a direction intersecting with the conveying direction of a substrate to correspond to the plurality of TFT forming areas set in a matrix on the substrate, is shifted in the direction intersecting with the conveying direction of the substrate, to thereby align the lenses in the lens array with the TFT forming areas on the substrate based on the alignment reference position. The laser beams are irradiated onto the lens array when the substrate moves and the TFT forming areas reach the underneath of the corresponding lenses of the lens array, and the laser beams are focused by the plurality of lenses to anneal the amorphous silicon film in each TFT forming area.

Abstract: A production method for a deposition mask is provided. The production method includes the steps of: forming a mask member having a structure in which a thin-board magnetic metal member having a through hole and a resin film contact tightly with each other; forming a mark that has a specified depth by irradiating a part of the film through the through hole of the mask member with laser beams; and forming an opening pattern that penetrates the film by irradiating a predetermined position with laser beams, using the mark as a reference.

Abstract: In a laser lighting device, a fly's eye lens and a condenser lens are disposed in an optical path of pulsed laser light emitted from a light source, and an electro-optical crystal element for continuously changing the deflection direction of the pulsed laser light with respect to the incident light and allowing the deflected light to pass therethrough is disposed in a position between the light source and the fly's eye lens or between the fly's eye lens and the condenser lens. The electro-optical crystal element is formed, for example, of a pair of electrodes and an optical crystal material disposed between the electrodes, and a voltage is applied between the electrodes to produce an electric field that changes the refractive index of the electro-optical crystal element. As a result, non-uniform illumination due to interference fringes produced by light having passed through the fly's eye lens can be reduced.

Abstract: To provide a production method including: a first step of forming a mask member in which a resin film and a magnetic metal member, which has first through-holes and second through-holes, are brought into close contact; a second step in which a peripheral edge of the magnetic metal member is bonded to one end face of a frame; and a third step in which a portion of the film in each first through-hole is irradiated with laser light to form an opening pattern, and a portion of the film in each second through-hole is irradiated with laser light to form a mask-side alignment mark.

Abstract: Exposure apparatus includes photomasks on which a mask pattern having the same shape as that of an exposure pattern exposed onto a surface of a TFT substrate held on a stage is formed, lens assemblies in which unit lens groups in each of which a plurality of convex lenses are arranged in a normal direction to the photomasks so that same-size erect images of mask patterns formed on the photomasks can be formed on the surface of the TFT substrate are arranged in a plane parallel with the photomasks and the surface of the TFT substrate held on the stage, and moving device that moves the lens assemblies in a plane parallel with the masks and the surface of TFT substrate held on the stage.

Abstract: This microlens array comprises hexagonal field diaphragms in inverted-image-forming positions, i.e., microlenses, a plurality of which are arranged in the direction perpendicular to a direction of scanning, and from which rows of microlenses are configured. Further, for three rows of microlenses, microlens rows are arranged with offset by (a length S) in a direction perpendicular to the direction of scanning such that triangular portions of the hexagonal field diaphragms overlap in the direction of scanning. Furthermore, microlens row groups, which are configured from three microlens rows, are arranged with offset in the direction perpendicular to the direction of scanning in increments of a minute amount of shifting F (for example, 2 ?m). Thereby, this scanning exposure device using a microlens array is capable of preventing exposure ununiformity even in the direction perpendicular to the direction of scanning.

Abstract: A scanning exposure apparatus uses a plurality of microlens arrays to project a mask exposure pattern onto a substrate. A CCD line camera detects an image on the substrate at this time, and using a first-layer pattern on the substrate as a reference pattern, detects whether or not the mask exposure pattern matches the reference pattern. In a case in which the patterns do not match, the microlens array is tilted from a direction that is parallel to the substrate, and the mask exposure pattern is made to match the reference pattern by using the microlens array to adjust the exposure area on the substrate. When the exposure pattern deviates from the reference pattern, it is thereby possible to detect the deviation during exposure and to prevent an exposure pattern misregistration, thereby enhancing the precision of the exposure pattern in an overlay exposure.

Abstract: A scanning exposure apparatus using microlens arrays, includes a plurality of microlens arrays is arrayed in a direction perpendicular to a scanning direction above a substrate to be exposed, and the microlens arrays are supported on a support substrate. The microlens arrays can be supported on a support substrate so as to be capable of being inclined from a direction parallel to the exposure substrate, relative to the direction in which the microlens arrays are arranged. The inclination angles of these microlens arrays are configured so as to gradually increase or decrease along the arrangement direction.

Abstract: A method of manufacturing of an alignment material film includes photoaligning the alignment material film by an exposure device to split each of sections of the alignment material film corresponding to picture elements of a liquid crystal display device into two parts in a width direction of the picture elements and exposing the alignment material film from different directions of each other. In the exposure device, each of sections of the alignment material film corresponding to the picture elements of the liquid crystal display device is split into two parts in the width direction of the picture elements and the two parts are exposed from the different directions of each other, whereby the alignment material film is photoaligned. The exposure device includes a first light source and a second light source for outputting exposure light.

Abstract: In an exposure device, picture elements or pixels of a liquid crystal display device are split into two parts in the width direction, and exposed from different directions, whereby an alignment material film is photoaligned. The exposure device causes two beams of exposure light outputted by two light sources (a first light source and a second light source to be transmitted through respectively different light transmission regions in a predetermined pattern of a mask, to irradiate regions of an alignment material film formed on a member for exposure, which regions correspond to split regions of pixels or picture elements. The exposure device causes the two beams of exposure light to mutually intersect on the optical path between the first and second light sources and the alignment material film.

Abstract: A pulsed laser oscillator includes at least one first electrooptical element that polarizes light according to an applied voltage and a voltage control unit that applies a voltage to the first electrooptical element and controls the voltage. The voltage control unit changes over time a voltage value applied to the first electrooptical element, to control a pulse width of laser light.