A system for determining a distance to a region of interest. The system may be used to adjust focus of a motion picture camera. The system may include a first camera configured to have a first field of view, and a second camera configured to have a second field of view that overlaps at least a portion of the first field of view. The system may include a processor configured to calculate a distance of the selected region of interest relative to a location by comparing a position of the selected region of interest in the first field of view with a position of the selected region of interest in the second field of view.

A lens system forms an image on an imaging element having a quadrilateral shape disposed on an optical axis. The lens system includes a second free-curved lens being asymmetrical with respect to the optical axis. A sag amount of the second free-curved lens in a circle separated from the optical axis by a length having a predetermined ratio with respect to a minimum image height has extrema outside of a first intersection points between a first surface passing through the optical axis and parallel to longer sides of the imaging element and the circle, and a second intersection point between a second surface passing through the optical axis and parallel to shorter sides of the imaging element and the circle. Each of the extrema is greater than the sag amount at the first intersection point or the second intersection point by 0.01 mm or greater.

Provided is an electronic device that implements image-capturing with a wide angle of view with a compact housing.

An electronic device according to the present disclosure includes: a display unit (2) configured to be deformable; and at least one first imaging unit (3) arranged on an opposite side of a display surface of the display unit (2) and configured to image incident light transmitted through the display unit. The display unit (2) may be foldable. Furthermore, at least a part of the display unit (2) may be bendable. Moreover, in the first imaging unit (3), an optical system used for image-capturing may be switchable in accordance with a shape of the display unit (2).

A camera module is provided, which includes a camera housing, a camera assembly including a lens, the camera assembly being accommodated in the camera housing and being rotatable about a first axis and a second substantially perpendicular to an optical axis of the lens with respect to the camera housing, and a guide plate connected to the camera assembly and the camera housing. The camera assembly further includes a. first corner area and a second corner area substantially facing a direction of the first axis and facing each other, and a third corner area and a fourth corner area substantially facing a direction of the second axis and facing each other. The fourth corner area includes a. chamfer area formed therein. The guide plate includes a first portion and a second portion rotatably connected to the camera assembly about the first axis, and a third portion and a fourth portion rotatably connected to the camera housing about the second axis.

An image pickup apparatus capable of eliminating a manual change of an image pickup direction and of easily obtaining an image while focusing attention on experience. A detection unit is worn on a body part other than a head of a user and detects an observation direction of the user. An image pickup unit is worn on the body part and picks up an image. A determination unit determines a recording direction in accordance with the observation direction. An image recording unit records an image corresponding to the recording direction from among a picked-up image. The detection unit and the image pickup unit are located on a user's median plane and under a user's jaw in a worn state where the user wears the image pickup apparatus. The detection unit is located at a nearer position to the jaw than the image pickup unit in the worn state.

An image pickup apparatus capable of eliminating a manual change of an image pickup direction and of easily obtaining an image while focusing attention on experience. A detection unit is worn on a body part other than a head of a user and detects an observation direction of the user. An image pickup unit is worn on the body part and picks up an image. A determination unit determines a recording direction in accordance with the observation direction. An image recording unit records an image corresponding to the recording direction from among a picked-up image. The detection unit and the image pickup unit are located on a user's median plane and under a user's jaw in a worn state where the user wears the image pickup apparatus. The detection unit is located at a nearer position to the jaw than the image pickup unit in the worn state.

A camera body includes an infrared LED that applies infrared light toward a face of a user that is a subject, and an infrared detection camera. The camera body determines a first irradiation amount of the infrared LED and a second exposure condition of the infrared detection camera in accordance with an LED OFF image acquired by capturing an image of the subject in a first exposure condition used by the infrared detection camera without the infrared light applied toward the subject, acquires the LED OFF image and acquires an image (LED ON image) of the subject irradiated with a first irradiation amount in image capture in a second exposure condition used by the infrared detection camera, and detect a face direction of the subject by using a difference image between these images.

There is provided an image processing device and method, and a program for enabling improvement in image quality in sensor shift imaging. When performing imaging while shifting the pixel phase of an image sensor having a two-dimensional pixel array, an image processing device adds up, for each pixel phase, a plurality of frames imaged in each pixel phase, and generates an addition frame for each pixel phase. The image processing device then combines the addition frames of the respective pixel phases. The present technology can be applied to a sensor shift imaging system.

There is provided an image processing device and method, and a program for enabling improvement in image quality in sensor shift imaging. When performing imaging while shifting the pixel phase of an image sensor having a two-dimensional pixel array, an image processing device adds up, for each pixel phase, a plurality of frames imaged in each pixel phase, and generates an addition frame for each pixel phase. The image processing device then combines the addition frames of the respective pixel phases. The present technology can be applied to a sensor shift imaging system.

An imaging system is for recording images of a bearing raceway and includes a platform having a surface sized to receive the bearing ring and an optical imager having a lens. A positioner secures the optical imager or a reflector oriented to reflect light to the optical imager lens and locates the optical imager lens or the reflector axially between first and second axial ends of the raceway and facing generally toward the raceway. A motor rotates the platform or the positioner relative to the other one of the platform and the positioner. A processor operates the optical imager and the motor such that the optical imager takes a series of images about the entire perimeter of the bearing raceway. The processor also indexes each image to a separate one of a plurality of arcuate segments of the raceway and constructs a panoramic image of the raceway.