An image reading device includes a mount table in which a mount surface is formed, a guide portion in which a guide surface is formed, the guide surface facing a side end face of a first portion of a booklet medium that is mounted on the mount table such that the mount surface faces the booklet medium, and an image capturer configured to capture an image of a second portion of the booklet medium, the second portion being different from the first portion, wherein a front cover slit is formed at an end of the guide portion on a side close to the mount surface.

Disclosed are a 3D scanning apparatus and a 3D scanning method. The 3D scanning apparatus includes a projector projecting patterns previously set onto a subject that is to be 3D scanned, a photographing unit photographing each of the patterns projected onto the subject at each of exposure levels previously set, a calculating unit calculating a depth value for each pixel of the subject based on the patterns photographed at each of the exposure levels, and a scanning unit 3D scanning the subject, which is photographed, based on the calculated depth value. The calculating unit calculates the depth value for each pixel of the subject by calculating the depth value for each pixel of the subject at each of the exposure levels and combining the depth values for the pixel, which are calculated at each of the exposure levels.

Disclosed are a 3D scanning apparatus and a 3D scanning method. The 3D scanning apparatus includes a projector projecting patterns previously set onto a subject that is to be 3D scanned, a photographing unit photographing each of the patterns projected onto the subject at each of exposure levels previously set, a calculating unit calculating a depth value for each pixel of the subject based on the patterns photographed at each of the exposure levels, and a scanning unit 3D scanning the subject, which is photographed, based on the calculated depth value. The calculating unit calculates the depth value for each pixel of the subject by calculating the depth value for each pixel of the subject at each of the exposure levels and combining the depth values for the pixel, which are calculated at each of the exposure levels.

Provided is an image reading apparatus that can read an image with highly accurate and stable density and color while illuminating the image with a color sequential projector thereof. The image reading apparatus according to the present invention includes: an image pickup unit configured to image an original that is mounted on a mounting surface; a projecting unit configured to project an image on the mounting surface by sequentially switching and emitting light of a plurality of colors; and a control unit configured to control the projecting unit so as to project a first black image, a first color image, and a second black image in this order during the imaging by the image pickup unit.

An apparatus may include a transparent platen, a command interface, a scanner unit, a controller and an indicator. The command interface is to receive externally originating instructions including a selected scaling value, other than 100%, for a scanning operation of a document resting against the transparent platen, wherein contents of the document to be scanned are proportionally magnified or shrunk based on the selected scaling value The controller controls a scanner unit to capture a portion of the transparent platen, the portion having borders automatically determined and proportionally changed by the controller based upon the selected scaling value. The indicator provides a visible indication of the portion.

An image recording method is disclosed. The image recording device has a camera having an image sensor and an objective lens, wherein the camera defines an image recording region, and the image sensor has a capture area having a plurality of image pixels which can be activated and read out in pixel groups, and a marking unit having a light source. The emission of the marking light is performed such that a visually perceptible light marking is generated inside the image recording region, and is performed in a predetermined manner to generate light marking within a light incidence region, which forms a subregion of the image recording region and the image capture is performed using chronologically offset collection, pixel group by pixel group, of exposure information, wherein the emission of the marking light is interrupted for the collection of the exposure information for each pixel group.

An apparatus may include a transparent platen, a command interface, a scanner unit, a controller and an indicator. The command interface is to receive externally originating instructions including a selected scaling value, other than 100%, for a scanning operation of a document resting against the transparent platen, wherein contents of the document to be scanned are proportionally magnified or shrunk based on the selected scaling value The controller controls a scanner unit to capture a portion of the transparent platen, the portion having borders automatically determined and proportionally changed by the controller based upon the selected scaling value. The indicator provides a visible indication of the portion.

An image reading device includes a mount table in which a mount surface is formed, a guide portion in which a guide surface is formed, the guide surface facing a side end face of a first portion of a booklet medium that is mounted on the mount table such that the mount surface faces the booklet medium, and an image capturer configured to capture an image of a second portion of the booklet medium, the second portion being different from the first portion, wherein a front cover slit is formed at an end of the guide portion on a side close to the mount surface.

An electronic device includes a photodetector, a notification light emitter, and a determination component. The photodetector detects reflected light of light from a projection device within a detection region, the projection device projecting the light in a projection region on a projection surface. The notification light emitter emits on the projection surface two notification lines of visible wavelength that approach each other towards the photodetector. The determination component determines that the projection region is at least partially located outside the detection region based on a detection result of the photodetector. The determination component further determines that an edge of the projection region that is located closest to the photodetector is substantially parallel to a line segment that connects ends of the two notification lines.

Various embodiments and methods relating to a scan area indicator are disclosed.