A beverage dispenser includes a nozzle to dispense a beverage. The beverage dispenser further includes a camera to capture an image of the beverage as the beverage is dispensed from the nozzle. The camera has a field of view that includes the beverage. The beverage dispenser further includes a light source that illuminates the field of view of the camera. The beverage dispenser further includes a computer. The computer analyzes the image of the beverage and determines a characteristic of the beverage.

A product inspection system includes an image acquisition system having a camera generating an inspection image of a product arranged between a plurality of mirrors. The inspection image has a plurality of sub images of different sides of the product. The inspection system has a calibration member with a plurality of correction patterns on different sides; the camera receives light from the calibration member reflected by the mirrors to generate a calibration image of the calibration member. A computer of the product inspection system receives the inspection image and the calibration image and determines a relative mirror position relationship between the mirrors. The computer forms a single spliced image of the product.

An automated optical double-sided inspection apparatus includes a first image-capturing portion, a second image-capturing portion, a platform, a first light-blocking portion, a second light-blocking portion, and a processing portion. The platform carries an external object. When the processing portion operates in a first capturing mode, the second light-blocking portion blocks visible light from passing therethrough, while the first light-blocking portion allows visible light to pass therethrough, so that the first image-capturing portion shoots a first side of the external object through the first light-blocking portion to obtain a first image. When the processing portion operates in a second capturing mode, the first light-blocking portion blocks visible light from passing therethrough, while the second light-blocking portion allows visible light to pass therethrough, so that the second image-capturing portion shoots a second side of the external object through the second light-blocking portion to obtain a second image.

An apparatus for inspecting plate-like bodies to inspect a side surface of a plate-like body with sheeted coating materials on a top side and bottom side of the plate-like body, is provided. The apparatus includes at least one light emitting unit configured to irradiate the side surface of the plate-like body with light. The apparatus includes at least one light receiving unit configured to receive light reflected with respect to the side surface of the plate-like body. The apparatus includes a conveying unit configured to move at least one among the light emitting unit and the plate-like body and to vary a position of the light on the side surface of the plate-like body, emitted by the light emitting unit. The apparatus includes a determining unit configured to determine whether the side surface of the plate-like body has a defect, by using the light emitted by the light emitting unit, upon occurrence of a condition under which the conveying unit varies the position of the light, on the side surface of the plate-like body, emitted by the light emitting unit.

Sensors, imaging systems, and methods for forming a sensor with a specified depth profile are provided. One sensor includes a substrate and one or more components attached to the substrate. The sensor also includes a sensor die having a thinned backside and energy sensitive elements configured for detecting energy illuminating the thinned backside of the sensor die. The sensor further includes discrete thermally-conductive structures formed between a frontside of the sensor die and the substrate by a flip-chip process thereby bonding the sensor die to the substrate and causing the thinned backside of the sensor die to have a pre-selected shape. At least a portion of the discrete thermally-conductive structures electrically connect the sensor die to the one or more components.

A device to detect and analyze defects in magnified scale images of a surface of a finished product illuminated with a blue light source and viewed by multiple image-capturing devices each focused on their own spot includes a supporting mechanism, a transmitting mechanism, a detecting mechanism, and a processor. The transmitting mechanism carries and transmits the product. The detecting mechanism includes a detecting frame, a blue light source assembly. The processor is used to connect to a camera assembly, and preprocess the image of the front of the product to obtain a detection and analysis of any defects of the front of the product.

A method for inspecting a pillar-shaped honeycomb structure includes steps of: capturing a pattern of reflected light from an end face with a camera and generating an image data of the pattern of the reflected light; distinguishing positional information of each of cells adjacent to an outer peripheral side wall and cells that are not adjacent to the outer peripheral side wall based on the image data of the pattern of the reflected light, and storing the distinguished positional information in a memory; capturing a pattern of transmitted light from the end face with the camera and generating an image data of the pattern of the transmitted light; measuring intensity of each transmitted light from the cells adjacent to the outer peripheral side wall to detect the cells having defective plugged portions that are adjacent to the outer peripheral side wall based on the generated image data of the pattern of the transmitted light and the positional information; and measuring intensity of each transmitted light from the cells that are not adjacent to the outer peripheral side wall to detect the cells having defective plugged portions that are not adjacent to the outer peripheral side wall based on the generated image data of the pattern of the transmitted light and the positional information.

The invention provides a defect inspection apparatus. The defect inspection apparatus includes: an illumination optical system configured to irradiate a sample with an illumination spot; a detection unit configured to detect, from a plurality of directions, reflected light from the sample irradiated with the illumination spot of the illumination optical system; a control unit configured to control a scan of the sample with the illumination spot of the illumination optical system by overlapping detection regions such that the detection regions partially overlap, the detection regions being detected by the detection unit configured to execute a detection from the plurality of directions when the sample is scanned with the illumination spot of the illumination optical system; and a signal processing unit configured to process a signal obtained by detecting the reflected light from the sample by the detection unit to detect a defect. The signal processing unit includes: a data integration unit configured to synthesize an integrated signal by processing the signal detected a plurality of times by overlapping the reflected light of the sample for each detection region by the detection unit; and a defect detection unit configured to detect the defect on a surface of the sample based on the integrated signal synthesized by the data integration unit.

A method for measuring the optical quality of a delineated region of a glazing, the delineated region being intended to be placed in front of an acquiring or measuring device such as a camera. The method is particularly suitable for measuring the optical quality of a delineated region of a transportation-vehicle glazing, such as an airplane or automobile windshield, in front of which an optical device for recording images or a device for measuring the environment outside the vehicle is placed with a view to enabling operation of an advanced driver-assistance system of the vehicle.

An inspection system for inspecting multiple surfaces of a substrate includes at least one illuminator that produces light at a first wavelength that is incident on the substrate at a first angle (e.g., normal) and light at a second wavelength directed that is obliquely incident on the substrate. An adjustment system adjusts the oblique angle. The substrate may be opaque to one of the wavelengths and at least partially transparent to the other wavelength. Detection optics collect backscattered light from the substrate and at least one detector generates a first image representative of the first surface of the substrate and a second image representative of a second surface or near the second surface of the substrate. The images may be compared to generate a third image representative of defects on or near the second surface of the substrate corrected for residual signals of defects on the first surface.