Abstract:
An overhead image reading apparatus 1 includes: an image-capturing unit 22 that captures an image of a medium S to be read from above when the medium S to be read is placed on a placement surface 2; a light source 21 that irradiates the medium S to be read with light when the image-capturing unit 22 captures the image of the medium S to be read; and a light blocking portion 25 that blocks light above an upper-end position of light emitted from the light source 21. As a result, the user 100 can be prevented from seeing light from the light source 21 with his/her eyes and from being dazzled with an unpleasant feeling by light from the light source 21 during reading on the medium S to be read.
Abstract:
A document image reading apparatus includes a sheet input tray, a sheet output tray, a sheet transfer channel, an image pickup device, a sheet pick-up module, and a transfer roller assembly. The sheet output tray is disposed under the sheet input tray, or the sheet output tray is disposed over the sheet input tray. After each of the plural documents on the sheet input tray is shot by the image pickup device, the document is fed into the sheet transfer channel by the sheet pick-up module. Then, the document is transmitted to the sheet output tray by the transfer roller assembly.
Abstract:
An image processing apparatus includes a camera, a support body, and an arm section including an arm that is rotatably attached to the support body and to a camera housing incorporating therein the camera. The image processing apparatus calculates a height of the camera measured from a set surface, using dimensional information of the image processing apparatus and inclination information indicating an inclination of the camera and an inclination of the arm. The image processing apparatus specifies a type of an object subjected for capturing by the camera using at least the height of the camera, and applies image processing specific to the specified type of the object to a captured image captured by the camera.
Abstract:
A device and method for scanning an object on a working surface, the device comprising: a body located adjacent to the working surface; two or more cameras mounted on the body at a location elevated adjacently above the working surface for capturing images of the object on the working surface, the two or more cameras being angled such that their range of image captures overlap and the common overlapping region of the range of image captures of the two or more cameras corresponds with the size of the working surface, the two or more cameras being spaced apart such that each of the two or more cameras captures a different angle of the common overlapping region; and a processing unit capable of correcting skewed images of the working surface captured by the two or more cameras and capable of converting the images captured by the two or more cameras into a three dimensional image.
Abstract:
One embodiment of a scanning stand for devices equipped with a digital camera comprising two inverted-V parts. One inverted-V part includes a sliding platform serving as a holder for a device equipped with a digital camera. Inverted-V parts are connected using nylon ribbons and the distance between inverted-V parts can be adjusted to accommodate documents of various thicknesses. A sheet of transparent acrylic or glass is included to provide means to flatten wrinkles or creases on documents and to straighten pages of bound material near the binding.
Abstract:
A device includes a processing system having a processor and a memory and an image capture component coupled to the processing system. The image capture component is configured to receive an image of a subject region within a field of view and an image of a control region within the field of view. The processing system is configured to process the image of the control region as a user input for processing the image of the subject region.
Abstract:
A pressing plate is used for an overhead scanner. The overhead scanner includes an imaging unit that images a medium to be read that is placed on a placement surface located under the imaging unit in the vertical direction and a light source that irradiates the medium to be read with light. The pressing plate includes a pressing plate main body for pressing the medium to be read from an upper side in the vertical direction and a plurality of anti-glare units arranged inside the pressing plate main body. The pressing plate main body is light transmissive. The anti-glare units block light reflected toward a side opposite to an incident light side from the light source, with respect to a vertical axis, among light reflected from the medium.
Abstract:
An image processing apparatus includes a camera, a support body, and an arm section including an arm that is rotatably attached to the support body and to a camera housing incorporating therein the camera. The image processing apparatus calculates a height of the camera measured from a set surface, using dimensional information of the image processing apparatus and inclination information indicating an inclination of the camera and an inclination of the arm. The image processing apparatus specifies a type of an object subjected for capturing by the camera using at least the height of the camera, and applies image processing specific to the specified type of the object to a captured image captured by the camera.
Abstract:
A material imaging apparatus includes a base, support pillar and imaging camera divided into a camera base and a camera neck. The camera is mounted via a first shaft on the pillar so as to be pivotable between a right horizontal position where an imaging lens is located on a base right side and a left horizontal position where the lens is located on base left side. The camera neck is mounted via a second shaft on the camera base so as to be rotatable between a downwardly vertical position where when the camera assumes the right or left horizontal position, the lens is directed to the base placement surface side and lens optical axis is substantially vertical to the base placement surface, and an upwardly vertical position where the lens is directed to a side opposite the base placement surface and the optical axis assumes a substantially vertical position.
Abstract:
The object of this invention is to provide a magnifying attachment to be attached to a camera by which a high magnification image can be obtained without appearing a part having no image in the image. The magnifying attachment has a magnifying objective lens (21A), a field lens (21B) for converting a light passed through the objective lens (21A) into collimated light, and a converging lens (21C) for focusing the collimated light on a camera lens (42). Light passed through the converging lens (21C) is converged on a pupil (42X) of the camera lens (42) with a solid angle exceeding the view angle of the camera lens (42).