Provided is a display control device including a display control unit that controls display, on a display unit, of highlighting an edge portion of a subject corresponding to a state of an image depending on an in-focus state of the subject in the image being within a predetermined in-focus near range.

An imaging apparatus includes an imager, and a controller. The imager is configured to capture a subject image formed via an optical system including a focus lens, to generate image data. The controller is configured to control a focusing operation for adjusting a position of the focus lens along an optical axis in the optical system according to an evaluation value for a focus state. In response to an instruction to reduce or increase a distance to a subject to be focused, the controller is operable to shift a start position to a direction according to the instruction in directions along the optical axis, the start position being a position of the focus lens for starting the focusing operation. The controller is operable to start the focusing operation from the start position after the shift.

A microscopic image capturing method includes: emitting a light beam from a light beam light source; detecting a spot image by a camera or a photodiode; focusing the spot image by an objective lens actuator moving an objective lens in the optical axis direction of the light beam with respect to a sample container; determining by a reflective surface identification unit whether the light beam has been applied to a defect on the basis of the spot image; when it is determined that the light beam has been applied to the defect, moving by an XY stage the sample container with respect to the objective lens in a direction orthogonal to the optical axis of the light beam in accordance with a prescribed condition; and, when the light beam has not been applied to the defect, capturing a microscopic image of a sample by using an illuminator.

Provided is an imaging apparatus and an imaging method that sets a type of a subject as a focusing target in each imaging. The imaging apparatus includes an image sensor that acquires an image, and an operation unit that selects a type of the subject as the focusing target in each imaging of the image acquired by the image sensor. In the case where the type of the subject as the focusing target is selected by the operation unit, a microcomputer detects an area of the subject of that type from the image and sets the detected area as an in-focus area of the image.

The focusing control device capable of preventing deterioration in precision of focusing control from being caused by an error in phase-difference depending on ambient temperature includes: an imaging element that outputs a pair of image signals deviated in one direction on the basis of one subject light image; a phase-difference detection section that detects a phase-difference between the pair of image signals; a temperature detection section; a correction section that corrects the in-focus position of the focus lens based on the detection phase-difference, which is the phase-difference detected by the phase-difference detection section, on the basis of the data in which the temperature, the focus lens position, and the information for in-focus position correction are associated with one another, the temperature which is detected by the temperature detection section, and the focus lens position; and a lens control section that moves the focus lens to the corrected in-focus position.

A focus control apparatus, comprises an area setting unit that sets a plurality of divided areas by dividing in a first direction and in a second direction, the first direction corresponding to a direction in which a focus state is detected; a focus detection unit that detects first information related to the focus state; a calculation unit that calculates defocus information on the basis of the first information; and a control unit that performs focus control on the basis of the calculated defocus information, wherein in a first mode in which the defocus information for the focus control is calculated by combining pieces of the first information, the calculation unit causes the part of the plurality of divided areas to vary in accordance with pieces of the first information.

The present invention provides an imaging device and a focusing control method capable of performing reliability determination of a phase difference AF at high speed. A phase difference AF processing unit (19) performs a correlation operation with respect to detection signal groups in first pairs P1, and performs a correlation operation with respect to detection signal groups in second pairs P2. A system control unit (11) compares a difference between a first correlation amount M1 which is a minimum correlation amount between the detection signal groups in the first pairs P1, among obtained results of the correlation operation with respect to the first pairs P1 and a second correlation amount M2 which is a minimum correlation amount between the detection signal groups in the second pairs P2, among obtained results of the correlation operation with respect to the second pairs P2 with a threshold value TH, to thereby determine a reliability of a focusing control based on the phase difference AF method.

Image processing device is image processing device that uses a plurality of images respectively having focusing positions different from each other to calculate distance information to a subject, and includes frequency converter, amplitude extractor, and distance information calculator. Frequency converter converts the plurality of images into frequency. Amplitude extractor extracts an amplitude component out of a phase component and the amplitude component of a coefficient obtained by converting the plurality of images into frequency. Distance information calculator calculates the distance information, by using lens blur data and only the amplitude component extracted by amplitude extractor out of the phase component and the amplitude component of the coefficient.

The present invention provides an imaging device and a focusing control method capable of reliably preventing the accuracy of a focusing control from being lowered even in a case where a signal level of a phase difference detection pixel is low. A system control unit (11) calculates, using detections signals of phase difference detection pixels (52A, 52B) obtained by each of two instances of imaging which are consecutively performed by an imaging element (5), first defocus amounts for each instance of imaging, adds up detection signals corresponding to the detection signals of the phase difference detection pixels (52), among captured image signals obtained by each of two instances of imaging, calculates a second defocus amount using signals after addition, and compares the plural of first defocus amounts and the second defocus amount to determine whether to perform a focusing control based on the second defocus amount.

The present disclosure relates to a solid-state imaging device that is designed to reduce reflection of incident light at the sidewall surface of the light blocking layer of each phase difference detection pixel, and to an electronic apparatus.

A solid-state imaging device according to one aspect of the present disclosure includes: a normal pixel for generating a pixel signal; and a phase difference detection pixel for generating a phase difference signal for image plane phase difference AF. In this solid-state imaging device, the normal pixel and the phase difference detection pixel each include a photoelectric conversion layer and a lens for gathering incident light onto the photoelectric conversion layer, the phase difference detection pixel includes a light blocking layer having an apertural portion with an aperture deviating from the optical axis of the lens, and an antireflection portion that prevents reflection of the incident light gathered by the lens unit is formed on the light blocking layer. The present disclosure can be applied to back-illuminated CISs.