Apparatuses and methods for inspecting a pharmaceutical cylindrical containers are provided. The apparatus includes a support device, a light emitting unit, and a light receiving unit. The support device supports the pharmaceutical cylindrical container and rotates the cylindrical pharmaceutical container around a longitudinal axis. The light emitting unit has a light source that illuminates the pharmaceutical cylindrical container with a detection beam while the support device rotates the pharmaceutical cylindrical container. The light receiving unit has a camera that acquires polarization information of the detection beam.

A gas sensing system can allow a gas sample to permeate hollow spaces within a porous scattering material. The porous scattering material can be substantially transparent at an illumination wavelength. An emitter can illuminate the porous scattering material and the gas sample with light having a spectrum that includes the illumination wavelength. A sensor can detect a level of light that has traversed the porous scattering material. Using, for example, the Beer-Lambert Law, the system can determine a concentration of the gas material in the gas sample. The scattering can greatly increase an optical path length through the porous scattering material, compared with a linear dimension of the porous scattering material. The increased optical path length can allow a gas chamber to shrink in size, thereby decreasing a size of the gas sensing system without a corresponding decrease in a sensitivity and/or an accuracy of the system.

In a gas sensing system, a light emitter can emit light through a gas sample toward a concave reflective surface. The reflective surface can redirect the emitted light to propagate through the gas sample toward a light sensor. Using, optionally, the Beer-Lambert Law, the system can determine a concentration of the gas material in the gas sample. By selecting a specified shape for the reflective surface, such as a complete or partial ellipsoid, and locating the light emitter and the light sensor in specified locations, such as at one or both foci of the ellipsoid, the gas sensing system can reduce variation in optical path length, from optical path to optical path, in the light that propagates from the light emitter, to the reflective surface, and to the light sensor. Reducing the variation in optical path length can improve an accuracy in determining the concentration of the gas material.

Aspects of the present disclosure are directed to a method and a device for carrying out chemical, biochemical and/or immunochemical analyses of liquid samples, which are present in a sample store of an automatic analyzer, with the aid of liquid reagents, which are present in at least one reagent store of the analyzer. In one embodiment, a analyzer is disclosed including cuvettes for holding the liquid samples and reagents, the cuvettes are arranged in at least one stationary, linear cuvette array. The analyzer further has an optical measurement unit with a stationary light-supplying unit which has at least one light distributor device that feeds the light from a plurality of LED light sources emitting in a spectrally different manner in the UV/VIS/NIR wavelength range into the inlet windows of the individual cuvettes of the cuvette array. The optical measurement unit further includes a stationary detection unit assigned to outlet windows of the cuvettes and further includes a plurality of photodiodes.

A detection system with a two-step homogenizing device (1) and with a receiver (42). Viewed in a field direction (54) of a photon field, the homogenizing device (1) is located between a measurement area (44) and the receiver (42). The homogenizing device (1) includes a first diffuser (10) and a second diffuser (12). The first diffuser (10) generates an intermediate photon field from an input photon field. The second diffuser (12) generates an output photon field from the intermediate photon field. The receiver (42) generates signals depending on the incident photon field.

The invention relates to an apparatus (1) for establishing the effect of active ingredients on nematodes and other organisms in aqueous tests, comprising a holder (40) for receiving a cell culture plate (50) with wells (57), in which the nematodes with the active ingredients can be filled, wherein the cell culture plate (50) has a bottom side (51), a top side (52) and a plurality of side faces, which extend between the bottom side (51) and top side (52), a camera (20) that serves to record images of preferably the bottom side (51) of the cell culture plate (50), and an illumination device (30) for illuminating the cell culture plate (50), wherein the illumination device (30) comprises a plurality of light sources. According to the invention, in the use position of the cell culture plate (50), provision is made for the light of a first light source (31) to enter the cell culture plate (50) from the outside through a first side face (53), the light of a second light source (32) to enter the cell culture plate (50) from the outside through a second side face (54), the light of a third light source (33) to enter the cell culture plate (50) from the outside through a third side face (55) and the light of a fourth light source (34) to enter the cell culture plate (50) from the outside through a fourth side face (56). Moreover, the invention relates to a method for adjusting the individual light sources.

The present invention relates to a method for in situ sensing of water stress in a plant by contacting a plant with a biosensor, where the biosensor comprises a material capable of giving a detectable response to changes in local water potential in the plant and detecting the detectable response thereby sensing water stress in the plant. The invention further relates to a method for determining water potential in a substance, a biosensor, a system for determining water potential in a substance, a method for determining water potential in a substance, a water potential measurement computing device, and a non-transitory computer readable medium having stored thereon instructions for determining water potential in a substance.

A display apparatus includes a display screen, and a controller that causes the display screen to display a composite image in which a first image acquired by imaging a space by a camera and a second image representing at least one type of aerosol existing in the space are combined. The position of the at least one type of aerosol as seen in a depth direction in the first image is reflected in the second image.

Imaging systems and methods with scattering to reduce source auto-fluorescence and improve uniformity. In some embodiments, the system may include a plurality of trans-illumination light sources configured to irradiate an examination region with different colors of trans-illumination light, while a same diffuser is present in each optical path from the trans-illumination light sources to the examination region. The system also may comprise an excitation light source configured to irradiate the examination region with excitation light. The system may be configured to irradiate the examination region with each of the trans-illumination light sources and, optionally, with the excitation light source, without moving parts in any of the optical paths from the trans-illumination light sources. The system further may comprise an image detector configured to detect grayscale images of the examination region, and a processor configured to create a color trans-illumination image from grayscale images.

An apparatus for carrying out Raman spectroscopy on a sample includes a light source for providing a beam of excitation radiation, and an optical system including a spectrograph. The spectrograph includes a grating that divides a beam of scattered light into a spectrum of spatially separated wavelength components and to direct a portion of the spectrum to a detector. The spectrograph includes: 1) a first lens system for focusing the portion of the spectrum onto the detector and 2) a second lens system-configured to provide a focal plane with focal point in the optical path for focusing the beam of excitation radiation and/or the beam of scattered radiation at the focal point. The apparatus including a reference sample arranged in the focal plane, in particular at the focal point, for obtaining a reference spectrum from the reference sample.