An information processing apparatus includes a communication unit configured to communicate with a camera configured to capture a third image which is one image in which left and right images are arranged, and a control unit configured to display the third image on a display unit and set a position of an enlarged range to which enlargement processing is to be applied by the camera in the third image displayed on the display unit, and the control unit converts the set position of the enlarged range based on a display format in which the third image is displayed on the display unit, and outputs an instruction to the camera.

A display method includes imaging a captured image containing a first marker placed on a surface and a second marker placed on the surface, and displaying a first image corresponding to the first marker and a second image corresponding to the second marker in an arrangement corresponding to an arrangement of the first marker and the second marker in the captured image on the surface.

Electronic equipment includes a processor, and a memory storing a program which, when executed by the processor, causes the electronic equipment to acquire a third image in which a first image captured via a first optical system and a second image captured via a second optical system and having parallax with respect to the first image are arranged side by side, apply predetermined processing to a target range included in the third image, and, wherein each of the first image and the second image is a circular region, set a rectangular region circumscribed around a circular region of the first image or a circular region of the second image as a movable region in which the target range included in the third image is movable.

A control apparatus includes a receiving unit that receives a captured image obtained by capturing an image in an optical finder of an image capture device in a state in which AF frames are displayed on the optical finder, a display unit that displays the captured image and a UI (user interface) for selecting at least one AF frame from AF frames displayed on the captured image, and a transmitting unit that transmits, to the image capture device, information for specifying the at least one AF frame selected via the UI.

An imaging apparatus includes a finder, a proximity detection unit configured to detect a proximity of an object to the finder, a receiving unit configured to receive a line-of-sight input, and a control unit configured to perform control to prohibit, after the proximity of the object is detected by the proximity detection unit, a specific function based on a position input by the line-of-sight input of the user from being performed until a first period of time has elapsed even in a case where a predetermined condition is satisfied, and allow, after the proximity of the object is detected by the proximity detection unit and the first period of time has elapsed, the specific function based on the position input by the line-of-sight input of the user to be performed, in response to satisfaction of the predetermined condition.

A display control apparatus includes an acquisition unit configured to acquire information about an in-focus position on a live view image, and a display control unit configured to perform control to display an item indicating the in-focus position on the live view image, based on the information acquired by the acquisition unit. The display control unit performs control to display a first item at a first in-focus position at which focus is continuously achieved, in a display form having higher visibility than in a display form of a second item to be displayed at a second in-focus position at which focus is not achieved at least last time, the first in-focus position and the second in-focus position being positions at which focus is currently achieved.

A vehicular vision system includes a camera and a repeater element at a vehicle. The repeater element is powered at least in part via power-over-coax and includes a de-serializer, a repeater and at least two serializers. The camera captures image data and outputs a camera output that includes serialized image data. The camera output is received at the repeater element and is de-serialized via the de-serializer to generate a de-serialized output. The de-serialized output is provided to the repeater and at least two repeater outputs are provided to the serializers. The serializers serialize the received repeater outputs to generate respective serialized outputs. The serializers each output the respective serialized output to a respective receiver of the vehicle. Each of the serialized outputs is representative of the serialized image data of the camera output received from the camera.

A lighting module which provides adjustably controllable illumination of a camera field of view of a camera module includes an adjustable collimator which can be adjustably positioned such that the emitted light beam is adjustably directed to illuminate various regions of various camera fields of view. The collimator can be adjusted via an actuator which adjustably positions the collimator relative to static components of the lighting module, including the light emitter. The light beam can be directed to illuminate a selected limited region of a camera field of view, based on identification of a subject within the limited region. The light beam can be adjustably directed based on user interactions with a user interface, including adjusting the light beam according to user-commanded beam angle, intensity, and direction. The light beam can be adjustably directed to illuminate a region according to different fields of view of different camera modules.

Provided is a display control device including a display control unit that controls display, on a display unit, of highlighting an edge portion of a subject corresponding to a state of an image depending on an in-focus state of the subject in the image being within a predetermined in-focus near range.

A method implementing dynamic camera presets. An image is received. A list of bounding boxes and a list of classification values are generated from the image. A set of tags, for the image, are generated from the list of bounding boxes and the list of classification values. A tagged image incorporating the set of tags into the image is presented. In response to a user input, a tag selection identifying a tag of the set of tags is received. View settings are adjusted to focus on a bounding box, from the list of bounding boxes, corresponding to the tag selection. An adjusted image is presented using the view settings.