The present disclosure relates to a beam analysis device for determining a light beam state, e.g., determining the focal position of a light beam, where the device has a partial beam imaging device having at least one first selection device for forming a first partial beam from a first partial aperture region of the first measurement beam, and an imaging device for imaging the first partial beam for generating a first beam spot onto a detector unit having a spatially-resolving detector. The beam analysis device also can have an evaluation unit for processing the signals of the detector unit, for determining a lateral position (a.sub.1) of the first beam spot, and for determining changes in the lateral position (a.sub.1, a.sub.1′) of the first beam spot over time. An optical system for focal position control with a laser optics and with a beam analysis device. Additionally, the disclosure relates to a corresponding beam analysis method and methods for focal position control of a laser optics and for focal position tracking of a laser optics.

A control device includes: a processor configured to obtain a first picture signal and a second picture signal, calculate first ranging information based on the first picture signal, calculate second ranging information based on the second picture signal, estimate a first subject distance corresponding to the first ranging information, estimate ranging information corresponding to a second focal position, perform arithmetic processing to determine degree of reliability of the first ranging information, and output a result of the arithmetic processing.

Disclosed is an electronic device including a camera module, and at least one processor, wherein the camera module includes a micro-lens array, a color filter array, and a light-receiving element array, wherein a first row of the micro-lens array includes a first micro-lens and a second micro-lens adjacent to the first micro-lens, wherein a first row of the color filter array includes a first color filter and a second color filter disposed under the first micro-lens, and a third color filter and a fourth color filter disposed under the second micro-lens, and wherein a first row of the light-receiving element array includes a first light-receiving element disposed under the first color filter, a second light-receiving element disposed under the second color filter, a third light-receiving element disposed under the third color filter, and a fourth light-receiving element disposed under the fourth color filter.

Disclosed is an electronic device including a camera module, and at least one processor, wherein the camera module includes a micro-lens array, a color filter array, and a light-receiving element array, wherein a first row of the micro-lens array includes a first micro-lens and a second micro-lens adjacent to the first micro-lens, wherein a first row of the color filter array includes a first color filter and a second color filter disposed under the first micro-lens, and a third color filter and a fourth color filter disposed under the second micro-lens, and wherein a first row of the light-receiving element array includes a first light-receiving element disposed under the first color filter, a second light-receiving element disposed under the second color filter, a third light-receiving element disposed under the third color filter, and a fourth light-receiving element disposed under the fourth color filter.

By moving at least one of a culture container having a plurality of wells or an imaging optical system that forms an image of an observation target in each of the wells, an observation position in the culture container is scanned to observe the observation target. In a case where an auto-focus control for each observation position is performed, a start timing of the auto-focus control for each observation position is switched on the basis of a boundary portion between the adjacent wells in a scanning direction of the observation position.

Various embodiments disclosed herein include techniques for operating a multiple camera system. In some embodiments, a primary camera may be selected from a plurality of cameras using object distance estimates, distance error information, and minimum object distances for some or all of the plurality of cameras. In other embodiments, a camera may be configured to use defocus information to obtain an object distance estimate to a target object closer than a minimum object distance of the camera. This object distance estimate may be used to assist in focusing another camera of the multi-camera system.

Provided is a control device that includes a calculation unit that calculates, on a basis of a result of capturing a subject image passed through a focus lens by using an imaging element including a plurality of phase difference detection regions, a focus position of each of the phase difference detection regions and a determination unit that determines a position of the focus lens on a basis of an average value of the focus positions of the phase difference detection regions calculated by the calculation unit and falling within a predetermined range from the focus position on an infinity side or macro side.

A focus adjustment control apparatus is provided which includes: a focus detection unit that calculates an evaluation value with regard to contrast of an image via an optical system to detect a focus adjustment state of the optical system; an acquisition unit that acquires from a lens barrel at least one of a maximum value and a minimum value of an image plane movement coefficient that represents correspondence relationship between a movement amount of a focus adjustment lens included in the optical system and a movement amount of an image plane; and a control unit that uses at least one of the maximum value and the minimum value of the image plane movement coefficient to determine a drive speed for the focus adjustment lens when the focus detection unit detects the focus adjustment state.

In a case where a microscope apparatus main body scans the bottom surface of the cultivation container by synchronously controlling a piezoelectric element and an actuator serving as optical axis-directional transport devices having different properties from each other, an objective lens of the imaging optical system is transported to a focus position in the optical axis direction.

In a case where a microscope apparatus main body scans the bottom surface of the cultivation container by synchronously controlling a piezoelectric element and an actuator serving as optical axis-directional transport devices having different properties from each other, an objective lens of the imaging optical system is transported to a focus position in the optical axis direction.