An exchangeable lens mountable on a camera body includes: a selection unit configured to select a first state wherein a movement range of a focusing optical system changing the exchangeable lens' focal position is limited and a second state which is different from the first state, and a transmission unit configured to transmit a first and second value which is equal to or smaller than the first value to the camera body in the second state, the first value indicating a relationship between the focusing optical system's moving amount and an image plane's moving amount at a position wherein the focusing optical system has moved, the second value indicating a relationship between the moving amount of the focusing optical system and the moving amount of the image plane, and transmit a value which changes depending on the focusing optical system's position as the second value in the first state.

An image capture control apparatus comprises a touch detector being capable of detecting a touch operation, a tracking unit that tracks a tracking target in a live view image captured by an image capturing unit, and a display control unit that, in response to the touch detector detecting a movement operation of moving a touch position, carries out control to display an indicator at a position, in a display, that is based on a movement amount of the movement operation, and a control unit configured to, in response to a predetermined amount of time elapsing after the touch for making the movement operation has been released, carry out control such that a tracking target determined on the basis of the position of the indicator is tracked by the tracking unit.

A camera device calibration method according to one embodiment comprises the steps of: acquiring first data including location values of a first zoom lens and location values of a first focus lens, corresponding to the location values of the first zoom lens; setting at least two location points of the first zoom lens; acquiring at least two location values, which correspond to the location values of the first focus lens corresponding to at least two location points of the first zoom lens; acquiring second data corresponding to a value between at least two location values of the first zoom lens; and setting, in a camera including the first zoom lens and the first focus lens, at least two location values of the first zoom lens and the first focus lens when a difference value, which is acquired by comparing the first data with the second data, is within a preset threshold range.

A camera device calibration method according to one embodiment comprises the steps of: acquiring first data including location values of a first zoom lens and location values of a first focus lens, corresponding to the location values of the first zoom lens; setting at least two location points of the first zoom lens; acquiring at least two location values, which correspond to the location values of the first focus lens corresponding to at least two location points of the first zoom lens; acquiring second data corresponding to a value between at least two location values of the first zoom lens; and setting, in a camera including the first zoom lens and the first focus lens, at least two location values of the first zoom lens and the first focus lens when a difference value, which is acquired by comparing the first data with the second data, is within a preset threshold range.

The imaging apparatus of the present technique is provided with an imaging unit configured to generate an image signal from a subject; and an evaluation value calculator configured to calculate an evaluation value that indicates a degree of focusing on the subject from the image signal obtained by the imaging unit for each block, and to output the evaluation value. The imaging apparatus is further provided with a combining unit configured to generate a focus assist video image based on the focus evaluation value, output from the evaluation value calculator, of each block, to combine the generated assist video image with the image signal, and to output the assist video image combined with the image signal; and a display unit configured to display an image in which the assist video image combined by the combining unit is combined.

The imaging apparatus of the present technique is provided with an imaging unit configured to generate an image signal from a subject; and an evaluation value calculator configured to calculate an evaluation value that indicates a degree of focusing on the subject from the image signal obtained by the imaging unit for each block, and to output the evaluation value. The imaging apparatus is further provided with a combining unit configured to generate a focus assist video image based on the focus evaluation value, output from the evaluation value calculator, of each block, to combine the generated assist video image with the image signal, and to output the assist video image combined with the image signal; and a display unit configured to display an image in which the assist video image combined by the combining unit is combined.

A method for switching focus between objects found simultaneously in an image area from a main camera where the focus of the main camera and a switch between different focus distances is controlled by a remote follow focus unit. A secondary system and a computer system are used to measure the distance to the first and second object simultaneously and continuously. Distance information from the secondary system regarding distance to the first object is used by the follow focus unit as a focus distance to set the focus of the main camera on the first object. Distance information from the secondary system regarding distance to the second object is used by the follow focus unit as a focus distance to switch the focus of the main camera from the first object to the second object. The secondary system and the computer system obtain distance information using a secondary camera system.

A method for switching focus between objects found simultaneously in an image area from a main camera where the focus of the main camera and a switch between different focus distances is controlled by a remote follow focus unit. A secondary system and a computer system are used to measure the distance to the first and second object simultaneously and continuously. Distance information from the secondary system regarding distance to the first object is used by the follow focus unit as a focus distance to set the focus of the main camera on the first object. Distance information from the secondary system regarding distance to the second object is used by the follow focus unit as a focus distance to switch the focus of the main camera from the first object to the second object. The secondary system and the computer system obtain distance information using a secondary camera system.

A lens driving apparatus includes a holder, a metal cover, a carrier, a sensing magnet, a printed circuit board, a position sensor, a coil and at least one driving magnet. The metal cover is coupled with the holder and has an opening. The carrier is assembled to a lens assembly having an optical axis, wherein the carrier is disposed in the metal cover and is movable along a direction parallel to the optical axis. The sensing magnet is coupled with the carrier. The printed circuit board is disposed near to one of the four lateral sides of the holder. The position sensor is disposed on the printed circuit board and corresponds to the sensing magnet. The coil is disposed on an outer surface of the carrier. One of the driving magnet is disposed in the metal cover and corresponds to the coil.

An image processing device is provided that includes: an acquisition unit that acquires a plurality of viewpoint images which are captured at a plurality of different viewpoints by an imaging unit; a detection unit that detects viewpoint-relevant information between the plurality of viewpoint images; a determination unit that determines a second imaging condition in which image change between before and after predetermined image processing is greater than that in a first imaging condition in which the plurality of viewpoint images are captured on the basis of the first imaging condition and the viewpoint-relevant information; and an output unit that outputs the second imaging condition determined by the determination unit.