Various embodiments disclosed herein include techniques for maintaining multiple cameras in focus on same objects and/or at same distances. In some examples, a subordinate camera may be configured to focus based on the focus of a primary camera. For instance, a focus relationship between the primary camera and the subordinate camera may be determined. The focus relationship may characterize the trajectory of the lens position of the subordinate camera with respect to the lens position of the primary camera. In various examples, the focus relationship may be updated.

An optical element driving mechanism is provided. The optical element driving mechanism includes a movable portion, a fixed portion, a driving assembly, and a support assembly. The movable portion is used for connecting to an optical element. The movable portion may move relative to the fixed portion. The driving assembly is used for driving the movable portion to move relative to the fixed portion. The movable portion is movable relative to the fixed portion through the support assembly.

Various embodiments are directed to techniques to automatically focus a digital camera. In one or more embodiments, a mobile electronics device may comprise a digital camera having a lens component and lens position component. A display may be coupled to the digital camera to reproduce an image with a first focal point. The digital camera may also include a focal point selection module coupled to the display to select a second focal point for the image and a focus control module coupled to the focal point selection module and the lens position component to provide focus control signals to the lens position component to focus the lens component on the second focal point. Other embodiments are described and claimed.

Before an observation region of an imaging optical system (14) reaches an observation position in the cultivation container (50), a vertical position of the cultivation container (50) at the observation position is precedently detected by an auto-focus displacement sensor. In a case where an objective lens is moved in an optical axis direction on the basis of the position, an error between the precedently detected vertical position of the stage (51) at the observation position and a vertical position of the stage (51) at a time point when the observation region of the imaging optical system (14) is scanned up to the observation position is acquired, and the objective lens is moved in the optical axis direction on the basis of the error.

Various embodiments disclosed herein include techniques for maintaining multiple cameras in focus on same objects and/or at same distances. In some examples, a subordinate camera may be configured to focus based on the focus of a primary camera. For instance, a focus relationship between the primary camera and the subordinate camera may be determined. The focus relationship may characterize the trajectory of the lens position of the subordinate camera with respect to the lens position of the primary camera. In various examples, the focus relationship may be updated.

A control apparatus for use with an optical apparatus includes an acquiring unit configured to acquire focus information from the optical apparatus, and a control unit configured to control, according to the focus information, movements of a first focus lens and an element that are independently movable in an optical axis direction. The control unit performs first driving that moves the element so as to reduce an image-plane moving amount caused by a movement of the first focus lens in simultaneously moving the first focus lens and the element.

An automatic focus system for an optical microscope that facilitates faster focusing by using at least two cameras. The first camera can be positioned in a first image forming conjugate plane and receives light from a first illumination source that transmits light in a first wavelength range. The second camera can be positioned at an offset distance from the first image forming conjugate plane and receives light from a second illumination source that transmits light in a second wavelength range.

Various embodiments disclosed herein include techniques for determining autofocus for a camera on a mobile device. In some instances, depth imaging is used to assist in determining a focus position for the camera through an autofocus process. For example, a determination of depth may be used to determine a focus position for the camera. In another example, the determination of depth may be used to assist another autofocus process.

Various embodiments disclosed herein include techniques for maintaining multiple cameras in focus on same objects and/or at same distances. In some examples, a subordinate camera may be configured to focus based on the focus of a primary camera. For instance, a focus relationship between the primary camera and the subordinate camera may be determined. The focus relationship may characterize the trajectory of the lens position of the subordinate camera with respect to the lens position of the primary camera. In various examples, the focus relationship may be updated.

A focus adjustment device comprising: a first detector which detects a focused state by a contrast detection system; second detectors which detect a focused state by a phase difference detection system; and a control unit which controls the first detector and second detectors so as to detect the focused state by the second detectors when detecting the focused state by the first detector.