An infrared (IR) imaging system for determining a concentration of a target species in an object is disclosed. The imaging system can include an optical system including a focal plane array (FPA) unit behind an optical window. The optical system can have components defining at least two optical channels thereof, said at least two optical channels being spatially and spectrally different from one another. Each of the at least two optical channels can be positioned to transfer IR radiation incident on the optical system towards the optical FPA. The system can include a processing unit containing a processor that can be configured to acquire multispectral optical data representing said target species from the IR radiation received at the optical FPA. One or more of the optical channels may be used in detecting objects on or near the optical window, to avoid false detections of said target species.

An optical scanning apparatus is provided. An objective lens receives a reflectance spectrum from a sample. A spectral detector detects a first path of the reflectance spectrum and outputs a spectral response. An imaging detector detects a second path of the reflectance spectrum and outputs an image response. A beam splitter is located between the objective lens and each of the spectral detector and imaging detector and splits the reflectance spectrum into the first path and the second path.

In an embodiment an optoelectronic apparatus includes a light detector having a bottom side, an upper side and at least one sidewall that extends between the upper side and the bottom side, a carrier having an upper surface on which the light detector is arranged such that the bottom side faces the carrier, at least one outer wall which is arranged on the surface of the carrier, the outer wall and the carrier forming a cavity with an opening in which the light detector resides, a filter covering the upper side of the light detector, the filter having a first threshold wavelength separating a first wavelength region from an adjacent second wavelength region, wherein the filter has a lower transmittance for light at wavelengths in the first wavelength region than for light at wavelengths in the second wavelength region and a first material layer covering the filter.

An adaptor for use with a colour measuring device is provided where the colour measuring device has a cavity, a sensor positioned at a closed end of the cavity for measuring colour of a surface, and a rim surrounding an open end of the cavity. The adaptor includes a plate for contacting the surface and covering the rim of the colour measuring device, the plate having a portion for occluding the cavity that is transparent, referred to as the transparent portion, and a releasable coupling mechanism fixed to the plate for coupling the plate to the colour measuring device such that the transparent portion of the plate covers the sensor of the colour measuring device.

A system for remote-controlling a spectrometer, which includes: at least one spectrometry device including a spectrometer and auxiliary modules, the spectrometry device being configured to measure spectrometry data on an object and/or a process; a control device configured to control the spectrometry device, the control device including an element for controlling the spectrometry device, an element for acquiring and processing the spectrometry data, and an element for remote communication; and at least one interface modules configured to communicate with the control device remotely. The remote-control device is configured to communicate with the interface module via Internet, and the spectrometry device is interchangeable. Also, a device for remote-controlling a spectrometry system that is configured to be used in a system for remote-controlling the spectrometer.

A mobile phone accessory for a smartphone, including a support and handling casing with an internal space, an inner face, an orifice for association with an AOI target, located within a light incident spot, and a rear wall portion, a lighting element, to illuminate the spot, a camera field of view, to make a reflection photo of the spot, a scattering plate, having a scattering opening with a center and a center, including high-opacity and low-opacity portions, which include color measurement targets, fixed on the face of the front wall portion, sidely with the measurement orifice, through the scattering opening is seen the spot, the scattering plate has from a high-opacity degree on and around the center to a low-opacity degree at the opposite and near the scattering opening, the scattering plate making homogeneous the lighting and the extension of the AOI target and color measurement targets.

Spectrometers include an optical assembly with optical elements arranged to receive light from a light source and direct the light along a light path to a multi-element detector, dispersing light of different wavelengths to different spatial locations on the multi-element detector. The optical assembly includes: (i) a collimator arranged in the light path to receive the light from the light source, the collimator including a mirror having a freeform surface; (2) a dispersive sub-assembly including an echelle grating, the dispersive sub-assembly being arranged in the light path to receive light from the collimator; and (3) a Schmidt telescope arranged in the light path to receive light from the dispersive sub-assembly and focus the light to a field, the multi-element detector being arranged at the field.

An integrated Raman spectrum measurement system and a modularized laser module are provided. The modularized laser module includes a laser emitter and an axis adjustment mechanism. The laser emitter is configured to emit a laser beam. The axis adjustment mechanism is connected to the laser emitter and configured to adjust at least two parameters of axis and orientation of the laser emitter. A beam splitter is disposed on the path of the laser beam. A signal collection unit is for collecting at least a part of a signal light from the beam splitter, wherein the signal light is converting by an object after receiving the part of the laser beam.

Soil penetrometers capable of measuring soil reflectance along the direction of insertion of the penetrometer are provided. The penetrometer can house an array of sensors, such as, for example, a Vis-NIR reflectance sensor, a load cell, a displacement sensor, and a moisture sensor. The reflectance data collected using the penetrometer can allow the interpretation and quantification of soil constituents and contaminants at high vertical resolution, such as 3 cm or more.

A spectroscopic module 1 is provided with a spectroscopic unit 8 and a photodetector 9 in addition to a spectroscopic unit 7 and a photodetector 4 and thus can enhance its detection sensitivity for light in a wide wavelength range or different wavelength regions of light. A light-transmitting hole 4b is disposed between light detecting portions 4a, 9a, while a reflection unit 6 is provided so as to oppose a region R in a light-absorbing substrate 2, whereby the size can be kept from becoming larger. Ambient light La is absorbed by the region R in the substrate 2. Any part of the light La transmitted through the region R in the substrate 2 is reflected to the region R by the unit 6 formed so as to oppose the region R, whereby stray light can be inhibited from being caused by the incidence of the light La.