A camera for detecting an object in a detection zone is provided that has an image sensor for recording image data, a reception optics having a focus adjustment unit for setting a focal position, a distance sensor for measuring a distance value from the object, and a control and evaluation unit connected to the distance sensor and the focus adjustment unit to set a focal position in dependence on the distance value, and to determine a distance value with the distance sensor via a variable measurement duration that is predefined in dependence on a provisional distance value such that a measurement error of the distance value and thus, on a recording of image data of the object, a focus deviation of the set focal position from an ideal focal position remains small enough for a required image sharpness of the image data.

A camera for detecting an object in a detection zone is provided that has an image sensor for recording image data, a reception optics having a focus adjustment unit for setting a focal position, a distance sensor for measuring a distance value from the object, and a control and evaluation unit connected to the distance sensor and the focus adjustment unit to set a focal position in dependence on the distance value, and to determine a distance value with the distance sensor via a variable measurement duration that is predefined in dependence on a provisional distance value such that a measurement error of the distance value and thus, on a recording of image data of the object, a focus deviation of the set focal position from an ideal focal position remains small enough for a required image sharpness of the image data.

A user may routinely wear or hold more than one computing devices. One of the computing devices may be a head-mounted computing-device configured for augmented reality. The head-mounted computing-device may include a camera. While imaging, the camera can consume power and processing resources that diminish a battery of the head-mounted computing device. To improve a battery life and to enhance a user's privacy, imaging of the camera can be deactivated during periods when the user is not interacting with the head-mounted computing device and activated when the user wishes to interact with the head-mounted computing device. The activation of the camera can be triggered by gestured data collected by a computing device other than the head-mounted computing-device.

Biological samples are prepared on a slide for physician or veterinarian interpretation in a case of a diagnosis for human or animal diseases. The biological samples are specimens taken from certain areas or body fluids of human or animal. The biological samples are placed on the slide and are made ready for an examination without any process or after physical processes. Physicians or veterinarians diagnose by interpreting the biological samples over a microscope. Digitizing data, usage of data processing techniques and automatic reporting are activities reducing a workforce of expert physicians or veterinarians with a developing technology by abandoning manual methods. As digital pathology and hematology are main technical fields, a system and integrated methods about digitizing, analyzing and storing biological samples are given.

Biological samples are prepared on a slide for physician or veterinarian interpretation in a case of a diagnosis for human or animal diseases. The biological samples are specimens taken from certain areas or body fluids of human or animal. The biological samples are placed on the slide and are made ready for an examination without any process or after physical processes. Physicians or veterinarians diagnose by interpreting the biological samples over a microscope. Digitizing data, usage of data processing techniques and automatic reporting are activities reducing a workforce of expert physicians or veterinarians with a developing technology by abandoning manual methods. As digital pathology and hematology are main technical fields, a system and integrated methods about digitizing, analyzing and storing biological samples are given.

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.

A microscope comprises a microscope objective, a camera and an imaging optical system for imaging an object through the objective to the camera along a first optical path. A projection optical system is provided for projecting a test image onto the object through the objective, and the imaging optical system is configured to image the projected test image from the object to the camera through the objective and along at least part of the first optical path. A focus adjustment system is provided for focusing the test image at the camera. Using the same objective and the same camera for both imaging and focusing allows reduction of the cost of the microscope in comparison with known microscopes that provide separate focusing systems.

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.

The image acquiring device 10 includes the voltage control unit 30 which generates first voltage information that can identify voltage applied to the first variable-focus lens 20A included in the first imaging unit 20 installed in a position where a subject can be photographed and whose focal length changes in accordance with an applied voltage, and generates second voltage information that can identify voltage applied to the second variable-focus lens 21A included in the second imaging unit 21 installed in the position where the subject can be photographed and whose focal length changes in accordance with an applied voltage, and the image judgment unit 40 which inputs images from the first imaging unit 20 and the second imaging unit 21, and selects one image taken at an in-focus position among input images, wherein the voltage control unit 30 generates information, as the first voltage information, that can identify each voltage in a time series of voltages whose values change with time, and generates information, as the second voltage information, that can identify that each of the voltages identified by the first voltage information is applied to the second variable-focus lens 21A after a predetermined period of delay.

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.