Described herein is a spectrometer device for optical analysis of at least one sample. The spectrometer device includes: at least one housing having at least one entrance window; at least one wavelength-selective element configured for separating incident light into a spectrum of constituent wavelengths, the wavelength-selective element being disposed within the housing; at least one detector device configured for detecting at least a portion of the constituent wavelengths, the detector device being disposed within the housing; and at least one contact sensor device for detecting a contact of the spectrometer device with the sample, where the contact sensor device includes at least one optical contact sensor device, where the optical contact sensor device is configured to detect an influence of the presence of the sample onto the transmission of the optical signal.

Systems and methods for determining illumination angle and viewing angle in color observation are described. The system includes an optical capturing device to acquire an image of its surroundings and a processing unit. When operated, the processing unit executes the following steps: identify a position of a light source in the image acquired by the optical capturing device; identify a position of a viewer in the image acquired by the optical capturing device; determine a first angular position of the light source with respect to the optical capturing device and a second angular position of the viewer with respect to the optical capturing device and provide the first angular position and the second angular position to define an actual viewing geometry.

An example system includes a light source, a first spectrometer, a second spectrometer, and an electronic control module. The light source is operable to emit light within a first range of wavelengths in a field of illumination. The first spectrometer is operable to measure first sample light reflected from an object within a second range of wavelengths and in a first field of detection. The second spectrometer is operable to measure second sample light reflected from the object within a third range of wavelengths and in a second field of detection. The electronic control module operable to determine, based on the measured first sample light and the measured second sample light, a distance between the system and the object, and determine, based on the measured first sample light and the measured second sample light, a spectral distribution of light corresponding to the object.

An apparatus comprising: a double path interferometer comprising a sample path for an object and a reference path; a source of linearly polarized light for the double path interferometer, a phase plate positioned in the sample path; means for superposing the sample path and reference path to create a beam of light for detection; means for spatially modulating the beam of light to produce a modulated beam of light; means for dispersing the modulated beam of light to produce a spatially modulated and dispersed beam of light; a first detector, a second detector, and means for splitting the spatially modulated and dispersed beam of light, wherein light of a first linear polarization is directed to the first detector and light of a second linear polarization, orthogonal to the first linear polarization, is directed to the second detector.

An apparatus and method for analyzing a tissue sample to provide depth-selective information includes at least one light source, collection light optics, and a light detector. The light source is configured to produce a light beam having one or more wavelengths of light that cause a tissue sample to produce Raman light signals upon interrogation of the tissue sample. The light beam is oriented to impinge on an exposed surface of the tissue sample at a point of incidence (POI), and oriented so that the light beam enters the tissue sample at an oblique angle relative to the exposed surface of the tissue sample. The collection light optics are configured to collect the Raman light signals emanating from the tissue sample at one or more predetermined lateral distances from the point of incidence. The light detector is configured to receive the Raman light signals from the collection light optics.

Provided are methods and systems for concurrent imaging at multiple wavelengths. In one aspect, a hyperspectral/multispectral imaging device includes a lens configured to receive light backscattered by an object, a plurality of photo-sensors, a plurality of bandpass filters covering respective photo-sensors, where each bandpass filter is configured to allow a different respective spectral band to pass through the filter, and a plurality of beam splitters in optical communication with the lens and the photo-sensors, where each beam splitter splits the light received by the lens into a plurality of optical paths, each path configured to direct light to a corresponding photo-sensor through the bandpass filter corresponding to the respective photo-sensor.

Methods and assemblies for aligning an optical device with a surface configured to receive a liquid coating and for measuring a parameter of a liquid coating are provided. An exemplary method for measuring a parameter of a liquid coating includes providing a mechanical carriage connected to a surface configured to receive a layer of the liquid coating. An exemplary mechanical carriage is configured to move to and from an operative configuration located at a set distance and orientation with respect to the surface. The method further includes locating an optical device in the mechanical carriage. Also, the method includes adjusting an orientation of the optical device within the mechanical carriage to an aligned orientation based on a relationship between the surface and a mechanical alignment feature on the optical device. The method further includes performing a parameter measurement operation with the optical device in the aligned orientation.

A colorimetric apparatus includes: an opening portion that is disposed at a bottom of an apparatus main body and that introduces light arriving from a measurement target to inside the apparatus main body; an incident light processing unit that processes light incident through the opening portion; a rotor that is provided at the bottom of the apparatus main body and is in contact with the measurement target, the rotor having an elliptical shape and being driven to rotate about a rotary shaft when the apparatus main body moves in a predetermined direction; a detector that detects displacement of the rotary shaft in a direction in which the rotary shaft advances and retreats with respect to the measurement target as the rotor rotates; and a control unit that receives a signal from the incident light processing unit and the detector.

The invention relates to the field of optical instrumentation and is intended for use in analyses in industrial laboratories and for scientific research purposes in analytical studies of the spectral characteristics of various materials. The technical result is an increase in the quality and accuracy of angular dependence measurements and measurements of complex prisms. A spectrophotometer comprises a housing, a measuring compartment and a source of monochromatic radiation, where the following are installed: a radiation source, a monochromator, an assembly of polarizers, a mirror element, a measuring channel with an assembly of photodetectors with a lens, a reference channel with an assembly of photodetectors with a lens; a rotary object table, capable of providing a triple exposure of the specimens when carrying out measurements, with a hollow rotation shaft and with specimens; and devices for moving the assembly of the measuring channel of the photodetectors with a vertical rotation shaft.

A system having an illumination source configured to illuminate a target object using broadband laser light. A dispersive element is configured to spectrally separate light received from the target object into different colors A focal plane array (FPA) is configured to: (1) receive the light from the dispersive element; (2) acquire spatial information regarding the target object in one dimension in the plane of the FPA; acquire spectral information in a second dimension in the plane of the FPA, wherein the second dimension is perpendicular to the first dimension; (4) obtain information regarding a distance from the FPA to the target object by obtaining different times of flight of at least two wavelengths; and (5) detect a single photon of light, thereby hyperspectrally imaging the target object in three dimensions.