A control apparatus includes a tilt driving unit configured to tilt at least one of an image sensor and an imaging optical system relative to a plane orthogonal to an optical axis, a focus driving unit configured to perform focus driving by moving a focus lens that constitutes at least part of the imaging optical system in an optical axis direction, and a controlling unit configured to control the focus driving unit and the tilt driving unit so as to adjust a focal plane to a predetermined surface. The controlling unit moves the focal plane in a vertical direction to the focal plane while maintaining the focal plane substantially parallel to the predetermined plane.

An apparatus includes a light intensity sensor arrangement, a focusing unit for focusing the light beam at a specified location on the light intensity sensor arrangement, and an adjustment unit which adjusts a relative position of the intensity centroid of the light beam in relation to a specified location on the light intensity sensor arrangement when there is a change in the beam angle present upon entry in the apparatus. The adjustment unit is configured to keep the relative position of the intensity centroid of the light beam in relation to the specified location on the light intensity sensor arrangement constant up to a specified maximum deviation. The maximum deviation corresponds to half the mean beam diameter upon incidence on the light intensity sensor arrangement.

An electronic apparatus comprises a sight position detection unit configured to detect region of a sight positon to a display unit which displays an object, and a control unit configured to perform control to, in a case where a state where the detected region of the sight position is not moving continues for a first time period, select an object corresponding to the region of the sight position, and in a case where a state where the detected region of the sight position is moving and a direction of movement of the region of the sight position and a direction of movement of an object satisfy a predetermined condition continues for a second time period, select the object.

Embodiments are directed to devices and methods including a time-of-flight sensor and a camera. In one embodiment, a device is provided that includes a time-of-flight sensor, distance estimation circuitry, a camera, and processing circuitry. The time-of-flight sensor transmits an optical pulse signal and receives return optical pulse signals corresponding to portions of the transmitted optical pulse signal reflected by an object. The distance estimation circuitry estimates a minimum distance to the object based on a time between transmitting the optical pulse signal and receiving a first portion of the return optical pulse signals, and estimates a maximum distance to the object based on a time between transmitting the optical pulse signal and receiving a second portion of the return optical pulse signals. The processing circuitry controls a focus distance and an aperture setting of the camera based on the estimated minimum and maximum distances to the object.

An augmented reality (AR) device including a variable focus lens of which a focal length may be changed by adjusting refractive power and adjusting the position of a focus adjustment region of the variable focus lens according to a direction of the user's view. The AR device may obtain an eye vector indicating a direction of the user's view using an eye tracker, adjust a refractive power of a first focus adjustment region of a first variable focus lens to change a focal length for displaying a virtual image, and complementarily adjust a refractive power of a second focus adjustment lens with respect to the adjusted refractive power of the first focus adjustment region.

A microscope-autofocus device for feedback-controlling a focal position of an imaging system of a microscope apparatus, wherein the imaging system includes a microscope objective, a monitoring beam source for creating a monitoring beam, a detector device for detecting a drift variation of an axial objective distance between the microscope objective and a sample by sensing the monitoring beam directed through the imaging system to the sample and reflected by the sample, and a feedback loop device for controlling the imaging system in dependency on the detected objective distance variation of the microscope objective.

A microscope apparatus includes an objective and an automatic focusing device. The automatic focusing device is an automatic focusing device of an active type that irradiates a specimen with automatic focusing light via the objective, and the automatic focusing device is configured in such away that an illumination light axis of the automatic focusing light passes through a position distant from an optical axis of the objective.

A camera focusing method, apparatus, and device for a terminal, and relate to the field of electronic device technologies to improve focusing precision of a terminal in a camera focusing process. The method includes obtaining a first confidence and a second confidence, determining a target ranging manner and a target object distance when the first confidence and the second confidence meet a preset condition, and determining a target position in a lens position interval to help a first camera and a second camera complete focusing.

A display apparatus including configuration of gaze sensors; gaze predictor module configured to process sensor data collected by aforesaid configuration to determine current gaze location and gaze velocity and/or acceleration, and to predict gaze location and gaze velocity and/or acceleration of user; image processing module configured to process input image for generating first image having first resolution and second image having second resolution, second resolution being higher than first resolution; first and second image renderers that render first and second image, respectively; optical combiner for optically combining projections of first and second images; and image steering unit configured to determine region of optical combiner onto which projection of second image is to be focused, and to make adjustment to focus projection of second image on said region; wherein second image renderer is switched off or dimmed during adjusting phase of image steering unit when said unit is making adjustment.

Embodiments are directed to devices and methods including a time-of-flight sensor and a camera. In one embodiment, a device is provided that includes a time-of-flight sensor, distance estimation circuitry, a camera, and processing circuitry. The time-of-flight sensor transmits an optical pulse signal and receives return optical pulse signals corresponding to portions of the transmitted optical pulse signal reflected by an object. The distance estimation circuitry estimates a minimum distance to the object based on a time between transmitting the optical pulse signal and receiving a first portion of the return optical pulse signals, and estimates a maximum distance to the object based on a time between transmitting the optical pulse signal and receiving a second portion of the return optical pulse signals. The processing circuitry controls a focus distance and an aperture setting of the camera based on the estimated minimum and maximum distances to the object.