Abstract: An optical position detection device includes a light receiving section receiving detection light reflected from a target object located in a detectable space through which detection light is radially emitted along an XY plane. The light receiving section includes a light receiving element and a concave mirror. A first cross section (XY cross section) of the reflective surface of the concave mirror is an arc, and a second cross section (YZ cross section) perpendicular to the first cross section is a quadratic curve. Therefore, in the in-plane direction of the XY plane, even light incident from an oblique direction with respect to the light receiving section is reflected by the concave mirror to the light receiving element. In the in-plane direction of the YZ plane, however, the range where the light reaches the light receiving element is limited via the concave mirror.

Abstract: In an optical position detection device, when light source sections emit detection light, a light detecting section detects detection light reflected from a object to detect the coordinates of the object. When seen from the detection space, the light detecting section is located inward from a plurality of light source sections, and each of the plurality of light source sections includes first and second light emitting elements. Therefore, the position of the object can be detected on the basis of a comparison result of the received light intensity in the light detecting section when the first light emitting element is turned on and the received light intensity in the light detecting section when the second light emitting element is turned on in both the case where the object is located outside a region between the light source sections and the case where the object is located inside the region.

Abstract: A backlight unit includes: an arrangement surface on which a plurality of light sources are arranged, and a plurality of reflection surfaces erected from a plurality of edges of the arrangement surface. The light emitted from the light sources and the light reflected from the reflection surfaces irradiate to an irradiation area surrounded by the reflection surfaces which are each inclined at an inclination angle smaller than 90 degrees with respect to the arrangement surface. At least one reflection surface includes a large inclination area inclined at a large inclination angle and a small inclination area inclined at a small inclination angle. The light source arranged close to the large inclination area is disposed closer to the outside frame of the irradiation area than the other light sources arranged close to the small inclination area in plan view from the irradiation area.

Abstract: An electro-optic device includes a first insulating substrate where a pixel electrode and a signal line are arranged on one surface side, a conductive layer formed on another surface of the first insulating substrate, and a conductive tape adhered to the conductive layer along at least one side of the first insulating substrate, where the conductive layer maintains a constant potential via the conductive tape.

Abstract: A mount structure includes a wiring board and a semiconductor device composed of a light-emitting device or a light-receiving device mounted on one surface side of the wiring board such that an optical axis thereof is oriented in a direction that extends along a board surface of the wiring board. On the one surface side of the wiring board, a first pad on which a first terminal of the semiconductor device is mounted, a second pad on which a second terminal of the semiconductor device is mounted, and a light-shielding conductive layer are formed using the same conductive layer. The first pad and the second pad are arranged on respective sides of an imaginary center line along which the optical axis of the semiconductor device extends and the light-shielding conductive layer is provided at a position beneath a light emission center or a light reception center of the semiconductor device in plan view.

Abstract: A backlight unit includes: an arrangement surface on which a plurality of light sources are arranged; a plurality of reflection surfaces which are erected from a plurality of edges of the arrangement surface and reflect a light from the plurality of light sources, wherein the light emitted from the light sources and the light reflected from the plurality of reflection surfaces irradiate to an irradiation area surrounded by the plurality of reflection surfaces; the plurality of reflection surfaces are each inclined at an inclination angle smaller than 90 degrees with respect to extension surface of the arrangement surface which extends toward the outside of the reflection surface; at least one reflection surface of the plurality of reflection surfaces includes a large inclination area inclined at a large inclination angle and a small inclination area inclined at a small inclination angle; and the light source arranged close to the large inclination area is disposed closer to the outside frame of the irradiatio

Abstract: A processing device includes a control section adapted to perform emission control of first and second light source sections based on a light reception result of a light receiving section adapted to receive a reflected light beam caused by an object reflecting irradiation light beams from the first and second light source sections, and a determination section adapted to determine a positional relationship of the object with respect to the first and second light source sections based on emission current control information for performing the emission control. The determination section determines the positional relationship of the object based on first period emission current control information as the emission current control information in a first period in which no object exists in the detection area and second period emission current control information as the emission current control information in a second period in which the object exists in the detection area.

Abstract: In an apparatus with a position detection function, a position detecting section detects the position of a target object on the basis of a result obtained by receiving detection light, which is emitted from a light source section for detection and reflected by the target object, using a light detection section. As seen from an emitting direction of the detection light, the light detection section is located inside a region surrounded by a closed circuit passing through a plurality of the light source sections for detection or inside a region pinched by the plurality of light source sections for detection. The plurality of light source sections for detection has a first light-emitting element, and a second light-emitting element located closer to the light detection section side than the first light-emitting element. The light source driving section alternately turns on the first light-emitting element and the second light-emitting element.

Abstract: In an optical position detecting device, a position detecting section detects the position of a target object on the basis of a result obtained by receiving detection light, which is emitted from a light source section and reflected by the target object, using a light detection section. As seen from an emitting direction of the detection light, the light detection section is located inside a region surrounded by a closed circuit passing through a plurality of the light source sections or inside a region pinched by the plurality of light source sections. The plurality of light source sections has a first light-emitting element, and a second light-emitting element located closer to the light detection section side than the first light-emitting element. The light source driving section alternately turns on the first light-emitting element and the second light-emitting element.

Abstract: An optical position detecting device includes: a translucent unit; a light source unit that emits detection light toward the translucent unit and forms with the detection light transmitted through the translucent unit a first light intensity distribution in which the intensity decreases as it becomes farther from the translucent unit; a light detecting unit that receives the detection light reflected by a target object located within the first light intensity distribution; and a position detecting unit that detects a position of the target object based on the intensity of light received by the light detecting unit.

Abstract: An optical detection device includes: a translucent unit that has elasticity; a light source unit that emits detection light toward the translucent unit; a light sensitive unit that is directed toward the translucent unit and has light sensitivity; and a detection unit that detects a target object based on the intensity of light received by the light sensitive unit.

Abstract: A position detection device includes: a light source adapted to form a light intensity distribution of a detection light beam; a first detector adapted to receive a reflected light beam of the detection light beam reflected by an object in a detection area where the light intensity distribution is formed; a transmissive member disposed between the detection area and the light source, and between the detection area and the first detector, and having a first surface directed toward the detection area and a second surface directed toward the light source; a second detector adapted to receive a light beam reflected by the second surface out of the detection light beam; a position detector adapted to detect the object based on the detection result in the first detector; and a light blocking member disposed between the second detector and the detection area, and adapted to block the reflected light beam.

Abstract: A projection display device having an image projection device adapted to project an image on a surface, and a position detection function of optically detecting a position of an object matter located between the surface and the image projection device, includes: a position detection light source section disposed in the image projection device, and adapted to emit position detection light beams toward the object matter; a light detector adapted to detect the position detection light beams reflected by the object matter; and a position detection section adapted to detect the position of the object matter in an imaginary plane intersecting emission directions of the position detection light beams based on a light reception result of the light detector, wherein the position detection light source section emits, as the position detection light beams, a first position detection light beam having a first intensity distribution, a second position detection light beam having a second intensity distribution having a hi

Abstract: A position detector detecting an object's position includes: first, second and third light sources emitting first, second and third position detection light beams to form first, second and third intensity distributions in a detection area, a highest intensity portion of the second intensity distribution being shifted from that of the first intensity distribution, a highest intensity portion of the third intensity distribution being shifted from a straight line connecting the highest intensity portions of the first and second intensity distributions; a light detector detecting the first, second and third position detection light beams reflected by the object; and a position detection section detecting a two-dimensional coordinate of the object in a detection plane set in the detection area by comparing the intensities of the first and second position detection light beams, and comparing the intensities of the second and third position detection light beams.

Abstract: An optical position detecting apparatus that detects a position of a target object in a detection region, includes: a light source device for position detection that emits position detection light to the detection region and forms an intensity distribution of the position detection light in the detection region; plural photodetectors that direct incident angle ranges to regions not overlapping one another in the detection region; and a position detecting device that detects the position of the target object on the basis of results of detection by the photodetectors of the position detection light reflected on the target object.

Abstract: A position detecting function-added projection display apparatus that optically detects a position of a target object positioned in a forward space in which an image is projected from an image projecting device, includes: a position detecting light source unit that forms a distribution of intensities of position detecting light in the forward space by emitting the position detecting light into the forward space; a plurality of photodetectors that are disposed in the image projecting device and have ranges of incident angles in directions of angles different from each other when the forward space is viewed from the image projecting device; and a position detecting unit that detects the position of the target object based on results of detection of the position detecting light reflected by the target object by using the photodetectors.

Abstract: An electro-optical device is provided which includes an electro-optical panel; and a metal frame configured to accommodate the electro-optical panel therein. The metal frame includes a plurality of side walls and corner portions provided between the side walls. A distal end of at least a portion of at least one of the side walls has a folding portion having a structure that inner surfaces are opposed to each other. At least one of the corner portions adjacent to the side wall having the folding portion has a seamless curved shape.

Abstract: A screen device with a light receiving element, the screen device being used in a display device with a position detection function, the display device forming an intensity distribution of a position detection light on a screen surface side of a screen member, the screen surface side on which an image is visually recognized, the display device detecting the position of an object located on the screen surface side of the screen member by detecting the position detection light reflected from the object, the screen device includes: a screen device main body provided with the screen member; and a light receiving element which is formed of a photodiode or a phototransistor fixed to the screen device main body and directs a light receiving section in a direction along the screen surface outside a screen surface in a state in which the screen member is spread.

Abstract: An apparatus is provided for application to a waste heat reuse system that recovers and reuses engine waste heat, and for controlling the amount of waste heat based on a requested heat amount of a heat utilization request. In the apparatus, an overlap angle between a valve-opening period of an intake valve and that of an exhaust valve of the engine is controlled based on an engine driving condition. Ignition timing of the engine is controlled to fall on maximum-efficient timing that minimizes fuel consumption in a current engine driving condition. When a requested heat amount cannot be satisfied, overlap-increase control is performed to increase an overlap angle, and ignition advance control is performed to advance ignition timing with reference to a maximum-efficient timing that corresponds to the increased overlap angle. Waste heat amount of the engine is controlled with the overlap-increase control and the ignition advance control.

Abstract: An electro-optical device includes an electro-optical panel and a holder that directly or indirectly holds the electro-optical panel. At least a part of the holder is formed of a metallic plate, and the at least part of the holder includes a turned-down portion formed by folding a part of a base portion of the metallic plate. The end of the turned-down portion forms a step that holds another component.