Focus detection apparatuses, control methods, and storage mediums for use therewith are provided herein. In a focus detection apparatus, a difference amplification unit performs processing for amplifying a difference between an A-image signal and a B-image signal and a CPU determines whether or not a focus state is a false in-focus state on a basis of a result of a correlation calculation performed by a correlation calculation unit on the A-image signal and the B-image signal. The A-image signal and the B-image signal are output from an imaging sensor that receives a pair of luminous fluxes passing through different pupil areas of an imaging optical system.

An image capturing apparatus capable of interchanging a lens unit includes a processing unit configured to perform image correction processing based on data acquired by an acquisition unit. In the image capturing apparatus, the acquired data includes information of a first shooting condition, configured in a discrete manner, information of a plurality of second shooting conditions provided for each information of the first shooting condition, and correction information corresponding to a combination of the information of the first shooting condition and the information of the second shooting condition.

Method and apparatus for enabling precise focusing are provided. The method includes obtaining an operation time of the photographing device in real time by a processor, searching a relationship table of preset times and focus range based on the obtained operation time to obtain a focus range corresponding to the obtained operation time; sending the obtained focus range to a driver by the processor, adjusting the distance between a lens and an image sensor based on the focus range by the driver, so that the lens may be located in the focus range, and to adjust the focus range in real time and improve the accuracy of focusing between the lens and the image sensor.

A focusing device comprises: an image capturing unit that captures a subject image formed via an optical system including a lens for executing focus adjustment and outputs an output signal; an edge detection unit that detects an edge signal among the output signal in correspondence to each color component among a plurality of color components contained in an image based upon the output signal; a calculation unit that calculates edge differential values each of which is a differential value of the edge signal in correspondence to the each color component; and a control unit that controls a moving direction along which the lens is to move based upon a comparison of the edge differential values.

The present technology relates to an image processing device and method, and a program for enabling easier recognition of the degree of focus of an image after photographing. A focus area determining unit calculates focus scores based on a photographed image, the focus scores indicating the degrees of focus of the respective areas in the photographed image. A warning control unit determines the degree of focus of a predetermined area in the photographed image in accordance with the focus scores for the respective areas, and issues a warning instruction in accordance with a result of the determination. The warning is issued by displaying the warning, outputting a warning sound, vibrating, or emitting light, for example. As the degree of focus is determined in accordance with the focus scores, neither blurring nor defocusing is caused, and the user can be prompted to check the degree of focus. The present technology can be applied to digital still cameras.

An image capturing apparatus is provided with a pixel array that has a plurality of image forming pixels and a plurality of focus detection pixels, a readout unit that reads out a pixel signal from the pixel array, an A/D conversion unit that has a first mode for A/D converting the pixel signal read out by the readout unit with a first resolution and a second mode for A/D converting the pixel signal read out by the readout unit with a second resolution that is higher than the first resolution, and a control unit that switches between the first mode and the second mode in accordance with the pixel signal read out from the pixel array.

A dome camera mechanism for an improved gimbal pan assembly which stops further rotation of an optical module of the dome camera in a pan direction using a cam latch.

An adjusting method of a camera module, a lens position control device, a control device of a linear movement device, and a controlling method of the same are provided in a state of the cameral module in which an imaging element and an actuator are combined. The camera module includes a position sensor (53) that detects a position of a lens (50) to output a detection position signal, a storage unit (541) that stores and rewrites a position code value corresponding to the position of the lens, a target position signal generation unit (542) that outputs a target position signal based on the position code value and the target position code value, and a control unit (543) that generates a control signal based on the target position signal and the detection position signal.

An imaging apparatus and method enables an automated extended depth of field capability that automates and simplifies the process of creating extended depth of field images. An embodiment automates the acquisition of an image stack or sequence and stores metadata at the time of image acquisition that facilitates production of a composite image having an extended depth of field from at least a portion of the images in the acquired sequence. An embodiment allows a user to specify, either at the time of image capture or at the time the composite image is created, a range of distances that the user wishes to have in focus within the composite image. An embodiment provides an on-board capability to produce a composite, extended depth of field image from the image stack. One embodiment allows the user to import the image stack into an image-processing software application that produces the composite image.

An imaging device includes a plurality of pixels each of which outputs at least one of an imaging signal and a ranging signal and performs a first readout operation that reads the imaging signal from a first pixel group of the plurality of pixels, and a second readout operation that, after the first readout operation and before a readout operation for next acquiring the imaging signal, reads the ranging signal from a second pixel group of the plurality of pixels. In the first readout operation, the imaging signal is not read from a third pixel group of the plurality of pixels, in a period from a reset of the first pixel group to a next reset of the first pixel group, the third pixel group is reset, and the second pixel group is selected from the third pixel group based on the imaging signal read by the first readout operation.