A light emitting device 401 includes a silicon substrate and a light emitting region including a lower electrode, a light emitting layer, and an upper electrode, and an exposure head is provided with a printed board on which light emitting devices 401 are arranged in a staggered form and a circuit portion 602 for controlling, on the basis of image data, a voltage of each of electrodes included in the lower electrode so that the light emitting device layer emits light and is for forming an image with a resolution corresponding to an arrangement interval of the lower electrode with respect to a crossing direction, and the circuit portion 602 is disposed together with the light emitting region on the silicon substrate. Costs on wire bonding and an area of a wiring board can be suppressed.

An exposure head configured to expose a photosensitive drum includes: a substrate; a plurality of strip-shaped semiconductor chips each including a plurality of light emitting elements that emit light and a drive circuit that drives the light emitting element, the plurality of semiconductor chips being arranged on the substrate; and a lens array configured to collect light from the light emitting elements on the photosensitive drum. The drive circuit operates between a first potential and a second potential, the light emitting element operates between a third potential and a fourth potential, and a potential difference between the third potential and the fourth potential is equal to or larger than a potential difference between the first potential and the second potential.

An image forming apparatus includes: an exposure head including a light emitting portion that includes a first electrode layer including a plurality of electrodes that are two-dimensionally arranged in a rotation direction and a rotational axis direction of a photosensitive member, a light emitting layer stacked on the first electrode layer, and a second electrode layer through which light is transmissible; and a controller configured to control a voltage applied to each of the plurality of electrodes in such a way that one pixel is formed by controlling the voltage applied to the plurality of electrodes arranged at different positions in the rotation direction, in which the plurality of electrodes are arranged in such a way that a pitch of the plurality of electrodes included in the first electrode layer in the rotation direction is an integer multiple of a resolution of an image formed by the image forming apparatus in the rotation direction, excluding an equal multiple.

An example operating method of an image forming apparatus includes detecting a position change of a beam with respect to a certain color in a main scanning direction, based on a change in a detection time at which the beam with respect to the certain color is detected by a beam detecting apparatus in the main scanning direction, detecting a position change of the beam with In respect to the certain color in a sub-scanning direction, based on a change in a detection time at which the beam with respect to the certain color is detected by the beam detecting apparatus in the sub-scanning direction, and correcting a value of at least one parameter used for alignment between an image of a reference color and an image of the certain color, based on the position changes of the beam in the main scanning direction and the sub-scanning direction.

An exposure head that exposes a photosensitive member to light includes a plurality of light-emitting element array chips mounted on one surface of a board, a connector mounted on the other surface of the board, and a first driver IC and a second driver IC that are connected to the connector and drive the light-emitting element array chips, wherein the first driver IC is placed on one side of the board with respect to the connector in the longitudinal direction of the board, and the second driver IC is placed on the other side of the board with respect to the connector in the longitudinal direction of the board.

Provided is an image forming apparatus configured to perform high-quality image formation regardless of an accuracy of mounting surface emitting element array chips. The image forming apparatus includes: an image data generating portion (401) configured to generate pixel data equivalent to 2,400 dpi; a joint correcting portion (1702) configured to correct a misregistration amount at a joint between a predetermined surface emitting element array chip and a surface emitting element array chip arranged adjacent to the predetermined surface emitting element array chip; and a resolution converting portion (1702) configured to convert a resolution of the pixel data from 2,400 dpi to 1,200 dpi. The joint correcting portion (1702) is configured to correct the misregistration amount at the joint with respect to pixel data obtained after the resolution thereof is converted by the resolution converting portion 1702.

An exposure head that exposes a photosensitive member to light includes a plurality of light-emitting element array chips mounted on one surface of a board, a connector mounted on the other surface of the board, and a first driver IC and a second driver IC that are connected to the connector and drive the light-emitting element array chips, wherein the first driver IC is placed on one side of the board with respect to the connector in the longitudinal direction of the board, and the second driver IC is placed on the other side of the board with respect to the connector in the longitudinal direction of the board.

A scanning suspension box is disclosed, enabling the creation of a 3D model of an object. The box is a sealable enclosure for receiving the object to be scanned. A camera coupled to a surface of the enclosure images the object to generate a three-dimensional model of the object, which does not move once contained in the box.

A scanning suspension box is disclosed, enabling the creation of a 3D model of an object. The box is a sealable enclosure for receiving the object to be scanned. A camera coupled to a surface of the enclosure images the object to generate a three-dimensional model of the object, which does not move once contained in the box.

The lens unit includes a first lens array including a plurality of first lens elements each of which has a first optical axis and which are arranged in an arrangement direction perpendicular to the first optical axis. A second lens array includes a plurality of second lens elements each of which has a second optical axis and which are arranged in the arrangement direction while facing the first lens elements. The second lens array is in a positional relationship relative to the first lens array such that the second lens array is rotated about a virtual line perpendicular to both the first optical axis and the arrangement direction as the rotational axis by 180 degrees. The optical axes of the lens elements located at the substantially centers of the lens arrays in the arrangement direction are arranged to substantially coincide with each other.