An apparatus includes a calculation unit that calculates a plurality of defocus amounts corresponding to a plurality of focus detecting frames obtained by dividing an area corresponding to a display frame, and a selection unit that selects one focus detecting frame which corresponds to one defocus amount used for an AF control. The selection unit changes an AF operation for selecting the one focus detecting frame based on the number of low contrast frames to the number of focus detecting frames or based on reliability selected from part of the area and a ratio of focus detecting frames having a high reliability in the area, or performs an AF operation for selecting the one focus detecting frame so that a high contrast frame is prioritized over a low contrast frame.

An apparatus includes a first acquisition unit configured to acquire an image, an analysis unit configured to perform an analysis process on the acquired image, a second acquisition unit configured to acquire a parameter for use in the analysis process on the image, a third acquisition unit configured to acquire superimposition information superimposed on the acquired image, an identification unit configured to, based on the acquired parameter, identify superimposition information that influences the analysis process on the image, and a processing unit configured to perform a process regarding drawing of the identified superimposition information.

A shooting method includes the following steps. A current display page is displayed and controls in a control region of the current display page are also displayed, where the controls includes a main shooting control and at least two special effect controls; when a target slide operation acting on a main display region of the current display page is received, each control is controlled to move; when the target control is the special effect control, a shooting page and a preview effect of a target shoot special effect are displayed on the shooting page, and when a first trigger operation acting on the trigger position is detected, shooting is performed by using the target shooting special effect; and when the target control is the main shooting control, the shooting page is displayed, and when a second trigger operation acting on the trigger position is detected, the shooting is performed.

Disclosed in the present invention is a head-mounted electronic vision aid device and an image magnification method thereof. The head-mounted electronic vision aid device comprising a memory unit, a processing unit, an image zooming unit, and at least one ranging unit; the ranging unit being configured to obtain distance data between a target object of interest to a user and the device and/or three-dimensional profile data of the object and output the data to the processing unit; the memory unit stores a correspondence table between the distance data and the magnification of the image zooming unit; the processing unit confirms the target object of interest to the user, performs operations on the distance data and/or the three-dimensional profile data of the object, and outputs an magnification matching the distance data to the image zooming unit according to the correspondence table; and the image zooming unit can automatically adjust to the matching magnification. For visually impaired users, accurate, intuitive and rapid automatic magnification of the target objects of interest can be realized on demand. Compared with the prior art, the repeated and tedious manual adjustment is avoided, and the user experience is greatly improved.

The present disclosure discloses an image special effect processing method and apparatus, an electronic device and a computer-readable storage medium. The method includes: in response to an instruction for adding a special effect object on an initial image, determining a target display region of the special effect object on the initial image, where the target display region is a foreground region or a background region of the initial image, the foreground region is an image region where a target object is located in the initial image, and the background region is an image region other than the foreground region in the initial image; and displaying a part of the special effect object located in the target display region on the initial image to obtain a target image.

Methods and devices related to determining image sensor settings using LiDAR are described. In an example, a method can include receiving, at a processing resource via a LiDAR sensor, first signaling indicative of location data, elevation data, and/or light energy intensity data associated with an object, receiving, at the processing resource via an image sensor, second signaling indicative of data representing an image of the object, generating, based at least in part on the first signaling, additional data representing a frame of reference for the object, transmitting to a user interface third signaling indicative of the data representing the frame of reference for the object and the data representing the image of the object, and displaying, at the user interface and based at least in part on the third signaling, another image that comprises a combination of the frame of reference and the data representing the image.

A display device displays a display object on a display part, controls a display on the display part, detects an indicator contacts the display part, and determines an input operation to the display part based on a detection result in the detecting. The display includes a first region being a detectable region and a second region being a part of the first region and a movable region where the display object moves according to the input operation. When a tap operation is detected, the display object is moved to coordinates of the tap operation being in the second region, and the display object is not moved toward coordinates of the tap operation being outside the second region. When a drag operation is detected, the display object is moved within the second region in accordance with a coordinate change due to the drag operation in the first region.

Mobile electronic devices comprising a first camera with a first field of view FOV.sub.1, a second, Macro camera with a Macro field of view FOV.sub.M smaller than FOV.sub.1, and a device screen that includes a first screen section configured to display first image data from the first camera and a second screen section configured to display second image data from the Macro camera when both cameras are focused to a distance equal to or smaller than 30 cm.

Electronic equipment includes an obtaining unit configured to obtain a third image in which a first image captured via a first optical system and a second image captured via a second optical system are arranged side by side, the second image having parallax with the first image and a setting unit configured to set, in the third image, a target area to which predetermined processing is to be applied, based on a user operation. The setting unit is configured to set the target area in such a manner that the item indicating the target area includes either one of the first image and the second image.

An electronic apparatus according to the present invention includes: a processor; and a memory storing a program which, when executed by the processor, causes the electronic apparatus to obtain a first live view image corresponding to a first optical image inputted via a first optical system and a second live view image corresponding to a second optical image inputted via a second optical system having a predetermined parallax with respect to the first optical system, and perform control to display, when displaying the first live view image and the second live view image side by side, an indicator indicating a part displayed during playback display in an angle of view of the first optical system such that the indicator is superimposed on the first live view image.