A spectrometer is provided. In one implementation, for example, a spectrometer comprises an excitation source, a focusing lens, a movable mirror, and an actuator assembly. The focusing lens is adapted to focus an incident beam from the excitation source. The actuator assembly is adapted to control the movable mirror to move a focused incident beam across a surface of the sample.

A color measurement apparatus to which a colorimeter that measures a color of a color measurement target is configured to be attached, includes a support base of the color measurement target, a carriage that supports the colorimeter, a gantry that supports the carriage, a first scanning mechanism that causes the carriage to perform scanning in a first direction on the support base, and a second scanning mechanism that causes the gantry to perform scanning in a second direction, in which the first scanning mechanism includes a first motor that generates a driving force for causing the carriage to perform scanning in the first direction, and a first transmission mechanism portion that transmits the driving force from the first motor to the carriage, and the first motor overlaps the gantry in a third direction.

Systems and methods here may be used for automated capturing and analyzing spectrometer data of multiple sample gemstones on a stage, including mapping digital camera image data of samples, applying a Raman Probe to a first sample gemstone under evaluation on the stage, receiving spectrometer data of the sample gemstone from the probe, automatically moving the stage to a second sample, using the image data, and analyzing the other samples.

A spectral imaging system includes an autocorrelator to generate different autocorrelations when the moving reflector in the autocorrelator is at different positions so as to reconstruct spectral images. The system also includes a position measurement system to measure the actual positions of the moving reflector when autocorrelations are taken. These actual locations, instead of the desired locations in conventional methods, are then used to reconstruct the spectral image. This approach can address the misalignment of the moving reflector from its desired location (due to external disturbances, slow actuator dynamics, and other factors) in conventional spectral imaging techniques and allow the development of high-resolution, high-stability, portable imaging spectrometers for the general public.

Systems and methods here may be used for automated capturing and analyzing spectrometer data of multiple sample gemstones on a stage, including mapping digital camera image data of samples, applying a Raman Probe to a first sample gemstone under evaluation on the stage, receiving spectrometer data of the sample gemstone from the probe, automatically moving the stage to a second sample, using the image data, and analyzing the other samples.

A colorimetry device includes a support base having a support surface for supporting a measurement target and a carriage unit configured to move in at least one of a first direction, which is a direction along the support surface, and a second direction, which is a direction along the support surface and which intersects the first direction as a moving direction, wherein the carriage unit includes an accommodation section to which a colorimeter, which is configured to measure color of the measurement target, is detachably and attachably accommodated and a first operation section that is a portion to which an external force is applied when the carriage unit is manually moved in the moving direction.

Handheld, broadband terahertz (THz) scanners, housings therefor and imaging systems are provided. The scanner may comprise a 2-Dimensional (2D) gimbaled mirror for beam steering. The 2D gimbaled mirror may comprise a single mirror mounted in a frame, a first motor and a second motor. The first motor and the second motor may be coupled to the frame. The mirror may be rotatable in a first axis of rotation and a second axis of rotation to scan light on a target in two dimensions. The first motor corresponds to the first axis and the second motor corresponding to the second axis. The 2D gimbaled mirror may be positioned within the housing such that the single mirror is positioned at a focus of a focusing lens. The focusing lens may be fixed within a housing. The scanner may also comprise a terahertz emitter and detector.

A sensor device for measuring radiation, in particular infrared radiation, UV radiation and/or visible light, having at least one sensor element, an energy supply unit for the sensor element, and an at least partially cylindrical container with a middle axis, wherein a container wall of the container is configured to be at least partially transparent, wherein the container is configured at least partially as a medication container. Furthermore, the invention relates to a sensor arrangement and a method for measuring the radiation.

A spectrometer is provided. In one implementation, for example, a spectrometer comprises an excitation source, a focusing lens, a movable mirror, and an actuator assembly. The focusing lens is adapted to focus an incident beam from the excitation source. The actuator assembly is adapted to control the movable mirror to move a focused incident beam across a surface of the sample.

A compact spectrometer includes an excitation light source configured to generate excitation light and arranged to illuminate a spot on a sample. A dispersive element includes at least one movable component and spatially separates output light emanating from the sample in response to the excitation light into a plurality of different wavelength bands. A moveable component of the dispersive element causes the plurality of different wavelength bands of the output light to be scanned across a detector. The detector includes at least one light sensor that senses the wavelength bands of the output light and generates an output electrical signal in response to the sensed output light.