This invention is capable of improving performance of a biochemical analyzer and facilitating the maintenance. A light source includes: a first LED that emits ultraviolet light and a second LED that has a light emission spectrum different from that of the first LED, the first LED and the second LED being disposed in parallel; a reflection surface that is opposite to the first LED and reflects light of the first LED; and a dichroic surface that is opposite to the second LED, reflects light of the first LED, and allows light of the second LED to penetrate. When an optical member including the dichroic surface is made to be the dichroic prism, the reflection surface reflects light of the first LED to the second LED side, and by using light source of a configuration having a light shielding unit between a light emission surface of the second LED and a dichroic prism, entering of a light emitted from the plural LEDs as a one light beam (beam) to an optical system of latter stage of the biochemical analyzer is enabled.

A detector (110) for determining at least one material property of at least one object (112) is proposed. The detector (110) comprises at least one projector (116) configured for illuminating the object (112) with at least one illumination pattern (118) comprising a plurality of illumination features (120); at least one first camera (122) having at least one first sensor element, wherein the first sensor element has a matrix of first optical sensors, the first optical sensors each having a light-sensitive area, wherein each first optical sensor is designed to generate at least one sensor signal in response to an illumination of its respective light-sensitive area by a reflection light beam propagating from the object (112) to the first camera (122), wherein the first camera (122) is configured for imaging at least one first reflection image comprising a plurality of first reflection features generated by the object (112) in response to illumination by the illumination features (120), wherein the first camera (122) is arranged such that the first reflection image is imaged under a first direction of view to the object (112); at least one second camera (124) having at least one second sensor element, wherein the second sensor element has a matrix of second optical sensors, the second optical sensors each having a light-sensitive area, wherein each second optical sensor is designed to generate at least one sensor signal in response to an illumination of its respective light-sensitive area by a reflection light beam propagating from the object (112) to the second camera (124), wherein the second camera (124) is configured for imaging at least one second reflection image comprising a plurality of second reflection features generated by the object (112) in response to illumination by the illumination feature (120), wherein the second camera (124) is arranged such that the second reflection image is imaged under a second direction of view to the object (112), wherein the first direction of view and the second direction of view differ; at least one evaluation device (126) configured for evaluating the first reflection image and the second reflection image, wherein the evaluation comprises matching the first reflection features and the second reflection features and determining a combined material property of matched pairs of first and second reflection features by analysis of their beam profiles.

An apparatus and method for real-time optical imaging of a tissue specimen. The apparatus comprises a primary imaging system configured to use an illumination source to acquire images of a tissue specimen through one or more spectrally separated channels, and configured to perform optical depth sectioning; an auxiliary imaging system, configured to acquire an auxiliary image of the tissue specimen; a specimen holder having a transparent window therewithin, window, the specimen holder comprising one or more position sensors, wherein the specimen holder is configured to be translatable in the specimen plane; a user input device configured to accept user input, wherein the specimen holder is configured to translate in response to the user input in real-time; a processing unit configured to execute a sequence of instructions on the sequence of images acquired by the primary imaging system, the auxiliary image, and at least one specimen holder position to generate a composite representation of the tissue specimen that includes a representation of cell nuclei in the specimen; and a display device configured to display the composite representation of the tissue specimen in real-time.

The system enables remote inspection of an object, such as an underwater steel pile, using a plurality of video cameras. The cameras are positioned on a frame along a plane substantially perpendicular to the axis of the object and spaced apart so as to enable inspection of the circumference of the object. Moving the frame along the surface of the object enables a video of the entire surface area of the object to be made. A plurality of wheels are mounted to the frame to provide rolling contact with the surface of the object and to cause the cameras to remain a fixed distance from the surface of the object. A plurality of springs are mounted between the frame and the wheels to further ensure smooth movement of the frame. A plurality of lights mounted to the frame illuminate the surface of the object during the inspection process.

The invention refers to a computer-implemented method of analyzing security documents having visible information and at least one of infrared and ultraviolet detectable information, the method comprising the steps of: receiving visible-color data of a first set of pixels of a first region of the security document in a first image of the security document and feeding the visible-color data to a convolutional neural network, CNN; receiving infrared, IR, and/or ultraviolet, UV, data of a second and/or third set of pixels of a respective second and/or third region in a respective second and/or third image of the security document and feeding the IR and/or UV data to the CNN; analyzing the visible-color data of the first set of pixels using the CNN to extract characteristics of the security document from the visible information; and analyzing the IR and/or UV data of the second and/or third set of pixels using the CNN to extract characteristics of the security document from the IR and/or UV information. Further, a corresponding system is provided.

Provided herein is a device related to imaging. In one embodiment, the device includes a side illumination unit, two window sample chamber, and refractive index matching. Also provided herein is an imaging apparatus comprising: a microscope; and a device comprising a side illumination unit, a two window sample chamber, and a refractive index matching. Further provided herein is a method of imaging a sample comprising: providing an apparatus comprising a microscope and a device comprising a side illumination unit, a two window sample chamber, and a refractive index matching; and imaging the sample in the apparatus.

A covered chamberless particulate detector includes a chamberless detector configured to produce a signal when particulate sensing events occurs, one or more optical emitters configured to emit one or more emitting cones of light, one or more optical sensors defining one or more receiving cones and configured to detect occurrence of particulate sensing events, and a protective cover defining an inside region and an outside region. Each of the one or more emitting cones of light is configured to overlap with each of the one or more receiving cones, thereby creating one or more sensing volumes which may be in the inside region, the outside region, or both regions. The protective cover can be transparent, partially transparent, or opaque, and can include apertures. The optical emitters and detectors can use one or more wavelengths, allowing discrimination of various airborne particulates.

Systems, devices, and methods for combined wafer and photomask inspection are provided. In some embodiments, chucks are provided, the chucks comprising: a removable insert, wherein the removable insert is configured to support a wafer so that an examination surface of the wafer lies within a focal range when the chuck is in a first configuration, wherein the removable insert is inserted into the chuck in the first configuration; and a first structure forming a recess that has a depth sufficient to support a photomask so that an examination surface of the photomask lies within the focal range when the chuck is in a second configuration, wherein the removable insert is not inserted into the chuck in the second configuration.

A mounting assembly for a camera on an inspection line, the assembly including a mount having a first and second end, the first end to fix the mount to an inspection line mounting surface, the first end configured to allow flexibility of positioning of the mount on the mounting surface, prior to fixing the mount to the mounting surface, and the second end configured to attach to a camera.

A beam shaper for an optical inspection tool includes a focal lens to focus an optical beam onto a target at an oblique angle of incidence and a phase modulator to substantially flatten a top of the optical beam in the plane of the target when the optical beam is focused onto the target at the oblique angle of incidence.