An imaging device includes a lens that guides, to an imaging element, light reflected from a subject, a wearing tool for wearing at least the lens on a wearing target, and at least one processor. The processor determines whether a first condition based on a positional relationship of the lens with respect to the wearing target is satisfied, determines whether a second condition that includes a condition based on the positional relationship of the lens with respect to the wearing target is satisfied, the second condition differing from the first condition, and makes an imaging parameter of at least one of the imaging element or the lens for when the first condition is satisfied and for when the second condition is satisfied different from each other.

Described herein is a spectrometer device. The spectrometer device is configured for determining at least one spectral or spectroscopic information of at least one object. The spectrometer device is configured for determining intensities of constituent wavelength signals of at least one light beam propagating from the object to the spectrometer device. The spectrometer device includes at least one distance detector configured for determining at least one distance information about a distance between at least one object and the spectrometer device, at least one pixelated imaging detector configured for determining at least one image of the object, and at least one evaluation device configured for determining at least one material information of the object by evaluating of at least one image of the object determined by the pixelated imaging detector. The evaluation device is configured for performing at least one spectroscopic analysis of the determined intensities of constituent wavelength signals.

A capturing apparatus includes a capturing unit which captures an object, and a mirror which is installed in an angle of view of the capturing unit so as to exist as a part of an image captured by the capturing unit. The mirror reflects light coming from a part, existing outside the angle of view of the capturing unit, of the object so that the light enters on the capturing unit.

A fingerprint identification module includes a lens, an optical sensor, and a light filtering component located between the lens and the optical sensor, where a thickness of an edge area of the light filtering component is greater than a thickness of a central area of the light filtering component, and a thickness of the light filtering component decreases gradually along a direction from the edge area to the central area.

A mobile phone-based miniature microscopic image acquisition device, and image stitching and recognition methods are provided. The acquisition device comprises a support, wherein a mobile phone fixing table is provided on the support. A microscope head is provided below a camera of a mobile phone. A slide holder is provided below the microscope head, and an lighting source is provided below the slide holder. A scanning movement is performed between the slide holder and the microscope head along X and Y axes, so that images of a slide are acquired into the mobile phone. The slide sample images acquired into the mobile phone can be stitched and recognized, and can be uploaded to the cloud to be processed by cloud AI, thereby significantly improving the accuracy and efficiency of cell recognition, greatly reducing the medical cost, and ensuring more remote medical institutions can apply such technology for diagnosis.

A mobile phone-based miniature microscopic image acquisition device, and image stitching and recognition methods are provided. The acquisition device comprises a support, wherein a mobile phone fixing table is provided on the support. A microscope head is provided below a camera of a mobile phone. A slide holder is provided below the microscope head, and an lighting source is provided below the slide holder. A scanning movement is performed between the slide holder and the microscope head along X and Y axes, so that images of a slide are acquired into the mobile phone. The slide sample images acquired into the mobile phone can be stitched and recognized, and can be uploaded to the cloud to be processed by cloud AI, thereby significantly improving the accuracy and efficiency of cell recognition, greatly reducing the medical cost, and ensuring more remote medical institutions can apply such technology for diagnosis.

In general, certain embodiments of the present disclosure provide a detection and avoidance system for a vehicle. According to various embodiments, the detection and avoidance system comprises an imaging unit configured to obtain a first image of a field of view at a first camera channel. The first camera channel filters radiation at a wavelength, where one or more objects in the field of view do not emit radiation at the wavelength. The detection and avoidance system further comprises a processing unit configured to receive the first image from the imaging unit and to detect one or more objects therein, as well as a notifying unit configured to communicate collision hazard information determined based upon the detected one or more objects to a pilot control system of the vehicle. Accordingly, the pilot control maneuvers the vehicle to avoid the detected objects.

A dosage hybrid inspection system includes a plurality of cameras selectively installed in sides of a rotating plate and a counter-rotating plate configured to vacuum suction a dosage along a circumference thereof. The cameras include a first camera unit including one or more camera arranged in the side of the rotating plate to photograph a top surface of a tablet when a bottom surface of the tablet is suctioned to the rotating plate, a second camera unit including a plurality of cameras arranged in the side of the rotating plate to photograph a portion of a circumferential surface of the tablet when the bottom surface of the tablet is suctioned to the rotating plate, a third camera unit including one or more camera arranged in the side of the counter-rotating plate to photograph the bottom surface of the tablet when the top surface of the tablet is suctioned to the counter-rotating plate, a fourth camera unit including a plurality of cameras arranged in the side of the counter-rotating plate to photograph another portion of the circumferential surface of the tablet when the top surface of the tablet is suctioned to the counter-rotating plate, wherein one or more camera of the second and fourth camera units is configured to photograph both edges of a capsule when a side surface of the capsule is suctioned to the rotating plate, and one or more camera of the first and third camera units is configured to photograph a circumferential surface of the capsule, and fifth and sixth camera units including a plurality of cameras further provided in the sides of the rotating plate and the counter-rotating plate to photograph another portion of the circumferential surface of the capsule which has not been photographed by the first and third camera units.

An ophthalmic device having a single or dual compartment configuration selectively emits infrared and visible light beams onto one or a pair of target eyes. The device performs eye fundus imaging and aids in the detection of ailments as indicated by anomalies in the pupillary reflex.

An ophthalmic device having a single or dual compartment configuration selectively emits infrared and visible light beams onto one or a pair of target eyes. The device performs eye fundus imaging and aids in the detection of ailments as indicated by anomalies in the pupillary reflex.