An image acquisition method includes defining a first optical sensor configuration of a matrix to acquire the image of a first celestial body of first nature, the first configuration having a plurality of unit pixels, defining at least one second optical sensor configuration of the matrix to acquire the image of the second celestial body of second nature, the second configuration having a plurality of macro-pixels formed by groupings of unit pixels, and selecting one of the optical sensor configurations, the selection being made according to the nature of the observed celestial body.

An object having a high attention degree is selected from objects detected by a detection means, brightness of a captured image is calculated by using an attention region corresponding to the selected object as a detection frame, and exposure control is performed based on the calculated brightness. The attention degree is evaluated higher with the decrease in the distance. Alternatively, the attention degree is evaluated higher as the direction becomes closer to the traveling direction. The attention region is made larger with the decrease in the distance to the object. It is also possible to judge the type of the object and determine the size of the attention region based on the result of the judgment. A subject to be paid attention to is made clearly visible.

Provided is an imaging apparatus capable of continuously imaging a natural video even though brightness is changed. In an imaging apparatus in which an exposure condition is set based on a characteristic of a transmittance control element, a first exposure condition range is calculated based on photometry of the imaging apparatus. Determination is made whether or not the calculated first exposure condition range is included in a second exposure condition range where a control range acquired by the transmittance control element is applicable. In a case where the calculated first exposure condition range is not included in the second exposure condition range, the exposure condition of the imaging apparatus is changed such that the first exposure condition range is included in the second exposure condition range.

An electronic device comprises a determination unit configured to determine a target remaining-capacity of a battery provided in an accessory device connected to the electronic device, based on an operation mode of the electronic device; and a power supply unit configured to supply power to the accessory device based on the determined remaining-capacity.

There is provided an imaging support apparatus including a processor, and a memory in which the memory stores a first trained model, the first trained model is a trained model used for control related to imaging performed by an imaging apparatus, and the processor is configured to generate a second trained model used for the control by performing learning processing in which a first image, which is acquired by being captured by the imaging apparatus, and a set value, which is applied to the imaging apparatus in a case where the first image is acquired, are used as teacher data, and perform specific processing based on a first set value, which is output from the first trained model in a case where a second image is input to the first trained model, and a second set value, which is output from the second trained model in a case where the second image is input to the second trained model.

An imaging device includes a varifocal lens and an imaging sensor which outputs a signal corresponding to light. The imaging sensor includes a photoelectric conversion unit which converts light into an electric charge, electric charge reading regions, transfer control electrodes, a gate control circuit which sequentially applies control signals to the transfer control electrodes to correspond to the position of the focal point of the varifocal lens, and a reading circuit which outputs a signal corresponding to the amount of the electric charge transferred to the electric charge reading regions. The gate control circuit repeats an operation of outputting each of the control signals when the position of the focal point is located in the focal ranges during a frame period.

Provided are an imaging device, an imaging method, and a program capable of changing assignment of functions to a plurality of operation units according to a use environment of the imaging device. An imaging device (1) includes: a plurality of operation units (265) provided on a plurality of surfaces of a device main body (101), respectively, and capable of being assigned functions; a memory (267) that stores assignment information indicating a relationship between a use environment and assignment of the functions to the plurality of operation units (265); and a processor (301), in which the processor (301) performs use environment determination processing of determining the use environment of the imaging device, and assignment setting processing of setting the assignment of the functions to the plurality of operation units on the basis of the assignment information of the memory, according to a result of the use environment determination processing.

An image processing device (1) includes an exposure control unit (102), a Δ pose estimating unit (109), and an integration unit (111). The exposure control unit (102) controls exposure by sequentially performing positive correction of increasing exposure from proper exposure or negative correction of decreasing exposure from the proper exposure as the exposure at a time of acquiring each of a plurality of image frames in time series in a predetermined execution order. The Δ pose estimating unit (109) estimates first position pose of the image processing device based on matching between image frames subjected to the positive correction and second position pose of the image processing device based on matching between image frames subjected to the negative correction. The integration unit (111) integrates the first position pose and the second position pose.

There is provided a solid-state imaging device including an imaging unit (211) that captures a first captured image, a light emission controlling unit (271) that controls emission of light from the light emitting unit, a decision unit (2331) that decides whether or not the emission of light is detected from within the first captured image, and a transmission controlling unit (2333) that controls, when the emission of light is detected, transmission of a second captured image or data based on the second captured image.

The present disclosure relates to an imaging device, an imaging method, and a program that make it possible to implement an appropriate auto white balance (AWB) lock desired by a user. As a shutter button setting for applying the AWB lock, any one of Shutter Halfway Down, Continuous Shooting, or Off can be select and set. Furthermore, a setting is configured in which an AWBL button is assigned to a custom button so that the AEB lock can be applied by either a hold operation or a toggle operation. The present disclosure can be applied to an imaging device.