An image reading device includes: light receiving sensors configured to read an image of a document conveyed in a sub-scanning direction and be arranged with an interval in a main scanning direction; one pair of document conveying rollers configured to be provided in front and back of the light receiving sensors in a document conveying direction; a detection unit configured to detect an image overlap amount in an image overlap area and/or an image missing amount in an image missing area; an adjustment amount determination unit configured to determine an adjustment amount for adjusting a distance between the document and the light receiving sensors based on the image overlap amount and/or image missing amount detected; and a drive unit configured to adjust a distance between the document and the light receiving sensors by displacing one of the document conveying rollers and light receiving sensors according to the adjustment amount.

A light-emitting component includes an insulating substrate, plural light-emitting elements, and plural thyristors. The plural light-emitting elements are disposed on the substrate and constituted by a first stacked semiconductor layer, the first stacked semiconductor layer being obtained by stacking plural semiconductor layers. The plural thyristors are constituted by a second stacked semiconductor layer disposed on the substrate such that the light-emitting elements and the thyristors are arranged side by side, connected to the plural light-emitting elements, respectively, and turn on to drive the light-emitting elements to emit light or to increase an emitted light amount, the second stacked semiconductor layer being obtained by stacking plural semiconductor layers that are different from the semiconductor layers of the first stacked semiconductor layer.

The present disclosure relates to a micro-scanning device that comprises a surface on which specimen to be scanned is positioned, and at least one micro lens configured to enable scanning of the specimen so as to obtain micro-details of the specimen. One or more micro lenses are installed below the flatbed surface in an array of movable configuration or in a stationary configuration. The device further incorporates a front panel to live-view micro-detail image of a specimen placed on the flatbed surface and incorporates means to focus, size, and zoom/scale the micro-detail image of the specimen. The device can be either a portable/handheld device or a stationary device and incorporates scan firmware to save and store or send copy of image incorporating micro-details on an associated/coupled computing device and/or in the internal memory of the scanner for performing any of stitching, printing, saving or sharing.

An imaging apparatus comprising a chassis, a light source for directing light along a first optical axis segment of the light path, at least a first fold mirror supported within the light path for redirecting light along a second optical axis segment, the at least a first fold mirror having a top edge, a first elongated lead member supported by the chassis, the first elongated lead member forming at least a first substantially straight surface that extends substantially parallel to the second optical axis segment, a first drive mechanism supported by the chassis and extending alongside and spaced apart from the first lead member, an area sensor aligned for movement with a segment of the light path, wherein the first lead member and the first drive mechanism are located to first and second different sides of the second optical axis segment and wherein each of the first lead member and the first drive mechanism are located at a height below the top edge of the at least a first fold mirror.

A scanner has a first mirror having a plurality of concavities configured to reflect light from a document; and a sensor configured to detect light reflected by the concavity; the concavity having an optical characteristic that differs according to position.

A document camera which operates with electric power supplied via a USB cable includes: an image pickup unit which picks up an image of a subject via a lens; a light source unit which emits light toward the subject; a drive unit which drives the lens; a detection unit which detects an amount of current supplied via the USB cable; and a control unit which controls an operation of the light source unit and the drive unit according to the amount of current detected by the detection unit.

Image scanning apparatus and method of operating an image scanning apparatus, the image scanning apparatus including a line scan detector and being configured to image a surface of an object mounted in the image scanning apparatus in a plurality of swathes, wherein each swathe is formed by a group of scan lines, each scan line being acquired using the scan line detector from a respective elongate region of the surface of the object extending in a scan width direction, wherein each group of scan lines is acquired whilst the object is moved relative to the scan line detector in a scan length direction.

A flatbed scanner includes a flatbed document scanner body accommodating a transparent plate for supporting a physical document and a document cover, which includes a sheet member with an expanse covering at least a substantial area of the transparent plate. The rectangular document cover has an underside and a movable carriage extending across the rectangular transparent plate in a transverse direction. The movable carriage carries a camera or an optical system for a camera. The sheet member of the rectangular document cover is magnetic or carries one or more magnetic plates, so as to be magnetically attracted towards the movable carriage and exert a pressing force on the physical document when supported on the rectangular transparent plate. A compressing force is thereby applied to an original document resting at an area at which the movable carriage currently is located while scanning a line of the original document.

An image scanning system comprises an image capture unit, a transmission unit, an adapter, a first driving unit and a second driving unit. The image scanning system uses the first driving unit connected with the adapter and the transmission unit to drive the image capture unit to move along an optical axis to instantly vary the distance between the image capture unit and the object. The image scanning system can realize high-precision submicron-scale transmission in simpler structure and lower cost.

An image scanning system comprises an image capture unit, a transmission unit, an adapter, a first driving unit and a second driving unit. The image scanning system uses the first driving unit connected with the adapter and the transmission unit to drive the image capture unit to move along an optical axis to instantly vary the distance between the image capture unit and the object. The image scanning system can realize high-precision submicron-scale transmission in simpler structure and lower cost.