A process for detecting foreign objects in a food-containing product stream comprises: forwarding the product stream, illuminating the product stream, generating raw data based on electromagnetic energy reflected from the product stream using a camera, and processing the raw data to generate classified image data corresponding with food product, foreign object(s), and background. A system for detecting foreign objects in the product stream comprises a forwarding device, an illuminator, a camera, and instructions in memory that form image data and classify the data as corresponding with food product, foreign objects, and background.

There is an inspection system including multiple inspection units configured to inspect substrates, wherein each of the inspection units includes: a tester configured to inspect a substrate; a moving part configured to hold and move the substrate relative to the tester; and a frame structure configured to accommodate the tester and the moving part, wherein the frame structure of one inspection unit includes: a first frame to be connected to a frame structure of another inspection unit; and a second frame that accommodates at least the moving part and is configured to move relative to the first frame to extract the moving part from the first frame.

A detection device for specimens includes an image sensor, a light-guiding structure, and a carrier. The image sensor includes a sensing area and a non-sensing area around the sensing area. The light-guiding structure is disposed on the image sensor. The light-guiding structure includes a central guiding portion, a reflection layer, and first guiding portions. The central guiding portion is located over the sensing area. The reflection layer is disposed on the image sensor and includes channels located over the non-sensing area. The first guiding portions are located in the channels, and connected to the central guiding portion and a side surface of the light-guiding structure. The carrier is disposed on the light-guiding structure, and has wells located over the sensing area. Each of the wells is configured to receive a specimen.

The invention relates to a system (15) for observing a plate (10) including wells (20), including, for each well (20): a source (40) comprising a light-emitting diode (60) capable of producing a light ray, a pinhole (70), and a light integrator (65), an optical sensor (185) able to collect the optical signal from the well (20), the system (15) being such that: a ratio between the length and the average transverse dimension (Dt) of each light integrator (65) is greater than or equal to 2.2, or at least one optical axis is off-centered relative to the propagation line, the ratio between the length and the average transverse dimension of the integrator being greater than or equal to 1.5.

An inspection system for inspecting rubber crumb includes a conveyor, lighting, a camera, and a controller. The conveyor is used to carry the rubber crumb. The lighting is positioned above the conveyor to illuminate the rubber crumb with at least 3,500 lumens. The camera is positioned adjacent to the lighting to take images of the illuminated rubber crumb in the lighted area. The controller receives the images from the camera and detects a contamination in the rubber crumb by determining whether there is a dark particle within the crumb. If a contamination is detected, it may be removed from the remaining rubber crumb.

A scalable reaction and detection system for automated high throughput sequencing of nucleic acids involving a combination of chemical processes and observation processes independent of the chemistry processes. Discrete functional units may be configured in a manner that allows the system to interchangeably utilize different sequencing reaction components in conjunction with discrete apparatus components for optical image collection and/or analysis.

The present disclosure proposes a colorimetric method that couples sensor design with image processing to enable automated evaluation of test results obtained by paper-based sensors. The proposed method can match ink color and dye used in colorimetric reaction in terms of their absorption in spectral range (e.g., red, green, blue). A near-zero absorption channel can then be used to normalize absorption channels and construct a composite image.

A detection device for specimens includes an image sensor, a light-guiding structure, and a carrier. The image sensor includes a sensing area and a non-sensing area around the sensing area. The light-guiding structure is disposed on the image sensor. The light-guiding structure includes a central guiding portion, a reflection layer, and first guiding portions. The central guiding portion is located over the sensing area. The reflection layer is disposed on the image sensor and includes channels located over the non-sensing area. The first guiding portions are located in the channels, and connected to the central guiding portion and a side surface of the light-guiding structure. The carrier is disposed on the light-guiding structure, and has wells located over the sensing area. Each of the wells is configured to receive a specimen.

An inspection system for inspecting rubber crumb includes a conveyor, lighting, a camera, and a controller. The conveyor is used to carry the rubber crumb. The lighting is positioned above the conveyor to illuminate the rubber crumb with at least 3,500 lumens. The camera is positioned adjacent to the lighting to take images of the illuminated rubber crumb in the lighted area. The controller receives the images from the camera and detects a contamination in the rubber crumb by determining whether there is a dark particle within the crumb. If a contamination is detected, it may be removed from the remaining rubber crumb.

There is an inspection system including multiple inspection units configured to inspect substrates, wherein each of the inspection units includes: a tester configured to inspect a substrate; a moving part configured to hold and move the substrate relative to the tester; and a frame structure configured to accommodate the tester and the moving part, wherein the frame structure of one inspection unit includes: a first frame to be connected to a frame structure of another inspection unit; and a second frame that accommodates at least the moving part and is configured to move relative to the first frame to extract the moving part from the first frame.