An image capable of confirming a focus position is generated without superimposing a peaking signal on a captured image. Therefore, an image processing apparatus according to the present technology includes an image signal generation unit that generates a plurality of image signals having frequency characteristics different from each other from one captured image signal, and a blending processing unit that blends the plurality of image signals on the basis of a blend ratio determined on the basis of a peaking signal for the one captured image signal.

The disclosure discloses a method and device for camera rapid automatic focusing. The method comprises: driving a lens to move to multiple different focus positions to acquire image data of a object, and calculating a corresponding estimated focus value in a first high frequency and a corresponding determined focus value in a second high frequency for each image data; calculating a rate of change between a current determined focus value and a previous determined focus value, and determining a direction of movement of the lens on the basis of the rate of change being either positive or negative; comparing the rate of change with a preset focus change threshold, and determining a speed of movement of the lens on the basis of a comparison result; and repeating said steps until the lens moves to a focus position corresponding to a maximum of the estimated focus values.

[Object] To improve both trackability of a focus position and focusing accuracy with respect to a subject. [Solution] An image capturing device includes: an imaging element having a light receiving surface including detection pixels that receive light passed through different regions of an exit pupil of an imaging optical system, and detect a phase difference between two images obtained by splitting the exit pupil; a first detection unit configured to execute at least any of first focus detection based on a phase detection autofocus (AF) method and second focus detection based on a contrast detection AF method; a focusing control unit configured to drive at least one optical member included in the imaging optical system toward a focusing position detected by the focus detection; and a second detection unit configured to detect a change in a subject image. In a case where a state in which a change amount of the subject image is less than a threshold continues for a predetermined period of time or more after the first focus detection, the first detection unit executes the first focus detection or the second focus detection.

A focus detection device includes: a sensor outputting a pair of focus detection signal sequences, each of which being made of a plurality of focus detection signals; a difference calculation unit obtaining a plurality of differences by sequentially calculating differences between focus detection signals corresponding to each other in the pair of focus detection signal sequences; a division unit dividing the pair of focus detection signal sequences into at least two pairs of partial signal sequences based on the plurality of differences; a focus detection parameter calculation unit calculating a first focus detection parameter according to a phase difference amount of a first pair of partial signal sequences and a second focus detection parameter in accordance with a phase difference amount of a second pair of partial signal sequences; and a focus adjustment parameter determination unit determining either the first or second focus detection parameters, as a focus adjustment parameter.

A digital camera controls a blur correction lens used to correct image blur occurring due to vibration applied to the digital camera. The digital camera controls a focus lens used for focus adjustment and a zoom lens used to change an angle of view in connection with driving of the blur correction lens during exposure to an image sensor.

The present disclosure provides methods for automated slide assessments made in conjunction with digital image-based microscopy. Automated methods of acquiring patient information and specimen information from prepared slides, and digitally linking such information into patient-tagged specimen data, are provided. Also provided are methods that include automatically identifying an optimal area for morphological assessment of a blood smear on a hematological slide, including methods for triggering the analysis of such an area, e.g., using an automated digital image-based hematology system. The present disclosure also provides devices, systems and computer readable media for use in performing processes of the herein described methods.

An image processing apparatus including: a display control unit configured to display highlighting corresponding to an in-focus degree of a subject included in an image on the basis of predetermined sensitivity and to perform control so that the sensitivity is determined depending on a predetermined condition.

An image capturing apparatus capable of executing autofocus by at least one of a phase difference detection method and a contrast detection method using an image signal obtained from a set focus detection region and from which an imaging optical system and a converter lens are detachable. The image capturing apparatus comprises: a conversion unit configured to convert aberration information indicating a spherical aberration of the imaging optical system based on a magnification and aberration information of the converter lens in a case where the converter lens is mounted; a calculation unit configured to calculate a correction value for correcting a difference between a result of the autofocus and a focus condition of a captured image; and a control unit configured to control a position of a focus lens based on the result of the autofocus that has been corrected using the correction value.

System of, and method for, trans-illumination imaging with use of interference fringes to enhance contrast and/or find focus. In an exemplary method, a coherence of light may be reduced upstream of a sample by scattering and mixing at least a portion of the light. The sample may be irradiated with the light of reduced coherence. An image of the sample may be detected, with the image being created with at least a portion of the light of reduced coherence that has passed through a plane defined by the sample. Image detection may be performed with the sample sufficiently defocused to form interference fringes in the image. The step of reducing a coherence of light may attenuate the interference fringes.

The embodiments include a system, comprising: a scanhead with a marking laser having a marking field. The system includes a vision system having a camera embedded in the scanhead having a field of view (FOV) within the marking field and an autofocus module which uses pixel information in an in-focus region of interest (ROI) of a target surface of a part to obtain a Z-axis focus in a vertical dimension above a two-dimensional (2D) plane. The marking laser selectively marks with a laser beam the target surface in the marking field based on at least the Z-axis focus.