A reading apparatus which is connected to an image forming apparatus that forms an image on a recording medium, the reading apparatus including: a supporting section which forms a reading surface for reading the image on the recording medium by contacting the recording medium on which the image is formed by the image forming apparatus; a conveyance section which conveys the recording medium so that the recording medium contacts the supporting section from a leading direction at a predetermined leading angle with respect to the reading surface and moves apart from the supporting section to an ejection direction at a predetermined ejection angle with respect to the reading surface; and a reading section which reads the image on the recording medium at a position where the reading surface is formed.

A light source module capable of combining light beams emitted by two semiconductor lasers mounted on the same substrate before entering a collimator lens to be focused on an image plane is provided. The light source module includes the two semiconductor lasers and a light beam combining element. The two semiconductor lasers are arranged so as to have parallel light axes. The light beams emitted by the two semiconductor lasers enter the light beam combining element which emits the light beams with respective light axes made closer to each other. An air conversion length of a total distance from a light emitting surface of one semiconductor laser to an exit surface of the light beam combining element, and an air conversion length of a total distance from a light emitting surface of the other semiconductor laser to the exit surface are equal to each other.

A light scanning apparatus includes a deflecting unit deflecting a light flux from a light source to scan a scanned surface with light flux in a main scanning direction, and an optical system including a first optical element. The first optical element includes a transmissive surface transmitting a first light flux deflected by deflecting unit at a first timing to guide first light flux to scanned surface, and a reflective surface totally reflecting a second light flux deflected by deflecting unit at a second timing different from first timing to guide second light flux to a light receiving element. The reflective surface is arranged on the same side as light source with respect to a sub-scanning cross section including an optical axis of optical system, and the following inequality is satisfied:

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where ? represents an incident angle of a principal ray of second light flux to reflective surface.

An image acquisition system according to the present invention includes: a display device including a display surface on which a subject can be mounted; and the image acquisition device that is disposed face-down at a position above the display device in a manner spaced apart from the display surface, the display device being disposed with the display surface face-up, and that acquires images of the display surface and the subject placed on the display surface, wherein the image acquisition device includes a transmission unit that transmits the acquired images, and the display device includes: a reception unit that receives the transmitted images; a relative-position calculation unit that calculates the relative position between the display device and the image acquisition device on the basis of the received image; and a display control unit that controls content displayed on the display surface on the basis of the calculated relative position.

In an example embodiment, an image processing system can be implemented, which includes a printing surface and a prism that splits light from an input light source into two parallel light beams indicative of a signal image. Two or more DMDs (Digital Micromirror Devices) can be utilized, wherein the two parallel light beams are directed to the DMDs for image processing, such that as the two parallel light beams are reflected out onto the printing surface, the two parallel light beams are recombined into a single image, thereby enabling heat dissipation while stitching said output of said at least two digital micromirror devices to a usable video path.

An image reading optical system includes an image reading unit including plural reading elements that are arranged in a first direction, a first reflective optical system configured to reflect reflection light which is irradiation light emitted from a light source and reflected on an object to be read, a second reflective optical system configured to condense the reflection light reflected on the first reflective optical system to the image reading unit, and an aperture stop including a plate shaped member formed with an aperture configured to regulate the reflection light reflected on the first reflective optical system in the first direction, the plate shaped member including at least one plate shaped piece bent at a preset angle with respect to the aperture along a tangent line of the aperture in the first direction.

An image forming device includes a controller and a laser scanning unit. The laser scanning unit includes a light source for generating a laser beam for discharging a photoconductive member to create an electrostatic latent image. A first memory is housed on the laser scanning unit and stores data unique to the laser scanning unit and laser beam as characterized during production. A second memory in communication with the controller, and separate from the first memory, stores data characterizing a family of similar laser scanning units of a same type. The controller is configured to read both the first and second memories to generate data to compensate for energy variations along a scan path of the laser beam on the photoconductive member during use. The data substantially reduces energy variation from one scan path to a next.

An image forming device includes a controller and a laser scanning unit. The laser scanning unit includes a light source for generating a laser beam for discharging a photoconductive member to create an electrostatic latent image. A first memory is housed on the laser scanning unit and stores data unique to the laser scanning unit and laser beam as characterized during production. A second memory in communication with the controller, and separate from the first memory, stores data characterizing a family of similar laser scanning units of a same type. The controller is configured to read both the first and second memories to generate data to compensate for energy variations along a scan path of the laser beam on the photoconductive member during use. The data substantially reduces energy variation from one scan path to a next.

A laser scanning unit for an image forming device includes a light source for emitting a laser beam, a scanning member having at least one reflective surface for scanning the laser beam onto an imaging surface across a plurality of scan lines, and driver circuitry for driving the light source to emit the laser beam. The driver circuitry has a first input for receiving a first signal indicating image information and a second input for receiving a second signal indicating shading information. The driver circuitry modulates the laser beam based on the first signal to form an image on the imaging surface corresponding to the image information and adjusts an output power of the modulated laser beam based on the second signal to substantially reduce energy variation across each scan line.

A laser scanning unit for an image forming device includes a light source for emitting a laser beam, a scanning member having at least one reflective surface for scanning the laser beam onto an imaging surface across a plurality of scan lines, and driver circuitry for driving the light source to emit the laser beam. The driver circuitry has a first input for receiving a first signal indicating image information and a second input for receiving a second signal indicating shading information. The driver circuitry modulates the laser beam based on the first signal to form an image on the imaging surface corresponding to the image information and adjusts an output power of the modulated laser beam based on the second signal to substantially reduce energy variation across each scan line.