An imaging apparatus includes a processor executing instructions which, when executed by the processor, cause the imaging apparatus to detect an object included in an image captured by an imaging unit, generate meta data conforming to annotated regions supplemental enhancement information (ARSEI) including positional information for the object detected from the image, and transmit transmission data including coded data generated by encoding the image and the meta data related to the image to an external apparatus, wherein, in a case where a variation of a parameter of a first object detected from a second image captured after a first image with respect to the parameter of the first object detected from the first image is less than a threshold value, meta data not including positional information for the first object in the second image is generated as meta data related to the second image.

An electronic device is provided. The electronic device includes a display module, a camera module, an ultra-wideband (UWB) communication circuit supporting UWB communication, and at least one processor is disclosed. The at least one processor may be configured to receive radar response information related to a radar reflection signal through the UWB communication circuit, analyze the radar response information to identify the presence of at least one alive object in a first image captured by the camera module, adjust autofocusing of the camera module based on detecting the presence of the at least one alive object, and display a second image captured through the adjusted autofocusing by the camera module on the display module.

The present invention relates to an end-to-end photography model for setting the light and exposure in a digital photography device with an external lighting system. The present disclosure is for a system and a method for automatically setting one or more image parameters for improved photography and image aesthetics. Specifically, the present invention is for automatically setting light and exposure which can be implemented on a personal electronic device with an integrated image capturing device having integrated and/or external illumination system. The embodiments described herein in general relate to a system and method for analyzing and controlling image parameters to set precise light and exposure for the electronic image capturing device, particularly for a personal electronic device, such as smartphone and tablet, with an integrated image capturing device.

A control apparatus includes a focus detecting unit configured to detect a defocus amount, a continuity determining unit configured to determine a continuity of a focus detection result, a characteristic detecting unit configured to detect characteristics of a main object and of surroundings of the main object, a controlling unit configured to change a parameter relating to a tracking operation based on the characteristics during the tracking operation and a focus adjusting unit configured to perform a focus adjustment based on the defocus amount, the continuity of the focus detection result and the parameter.

The invention relates to an autofocusing method for an imaging device (for semiconductor lithography) comprising an imaging optical unit, an object to be measured and an autofocusing device having a reflective illumination, comprising the following method steps: a) defining at least three basis measurement points M(x.sub.j, y.sub.j) on a surface of the object, b) determining the deviation A.sub.z(M)j of a nominal position of the surface of the object from the focal plane of the autofocusing device at the defined basis measurement points M(x.sub.j, y.sub.j), c) storing the deviations A.sub.z(M)j from at least three basis measurement points M(x.sub.j, y.sub.j), d) using the stored deviation A.sub.z(M)j for determining a deviation A.sub.z(P)k at an arbitrary point P(x.sub.k, Y.sub.k) of the surface, and e) using the deviation A.sub.z(P)k for focusing onto the point P(x.sub.k, Y.sub.k).

An apparatus configured for image processing comprises one or more processors configured to determine data associated with a distance between an object and the apparatus and determine a plurality of lens positions of a camera lens based on the data associated with the distance between the object and the apparatus. The one or more processors are further configured to determine, for each one of the plurality of lens positions, a respective focus value to generate a plurality of focus values. To determine, for each one of the plurality of lens positions, the respective focus value, the one or more processors are configured to determine, for each one of the plurality of lens positions, phase difference information. The one or more processors are further configured to determine a final lens position based on the plurality of focus values.

The present disclosure relates to the technical field of terminals, and particularly relates to a method and device for terminal-based object recognition, and an electronic device. The method includes: receiving a function instruction for simulated magnifier input to a terminal by a user; activating a camera of the terminal according to the function instruction for simulated magnifier; determining an object to be recognized based on an object photographed by the camera; acquiring a physical distance between the object to be recognized and the camera, and acquiring a preset focal length corresponding to the physical distance; generating, according to the preset focal length, a first image corresponding to the object to be recognized, and displaying the first image; performing image processing and image recognition on the first image; and displaying information of the object to be recognized at the terminal according to a result of image processing and image recognition.

An imaging apparatus comprising: a display configured to display information; an image sensor configured to capture an image of a subject to generate image data; an audio input device configured to input audio to generate an audio signal indicating sound to be collected during image capturing with the image sensor; a detector configured to detect a subject region which corresponds to the subject in the image data; a controller configured to determine a main subject and a sound collection target for the audio signal, according to a subject region detected by the detector. When the detector detects a plurality of subject regions, the controller controls the display to display first identification information indicating a subject which is the main subject and is the sound collection target and second identification information indicating a subject which is different from the main subject and is the sound collection target distinguishably from each other.

A technique for strobe shooting using automatic irradiation direction control. A strobe device includes a light emission section that emits light, and a drive unit that changes an irradiation direction of light emitted from the light emission section. Exposure conditions set to the camera are notified to the strobe device, and light emission conditions are set according to the exposure conditions. The irradiation direction of light emitted from the light emission section is determined based on the exposure conditions and the light emission conditions.

A video recording method is disclosed. The method includes receiving video recording instructions; monitoring an object distance between an object to-be-recorded and a lens of a camera; if the object distance between the object to-be-recorded and the lens is within a first range, controlling a first camera to focus based on the object distance, wherein different object distances within the first range correspond to different focus points; and if the object distance between the object to-be-recorded and the lens is within a second range, controlling a second camera to focus at a hyperfocal length, wherein different object distances within the second range correspond to a same focus point.