A spectroscopic unit and spectroscopic device according to the present invention are provided with a filter that is provided with a plurality of optical filter elements disposed in order from the entrance side to the exit side of light under measurement and has different transmission wavelengths corresponding to entrance positions along a first direction. A first optical filter element from among the plurality of optical filter elements is tilted with respect to a second optical filter element disposed adjacently to the first optical filter element as a result of the first optical filter element being rotated by a prescribed angle with a third direction that is perpendicular to both the first direction and s second direction from the entrance side to the exit side as the axis of rotation thereof or being rotated by a prescribed angle with the first direction as the axis of rotation thereof.

Systems and methods for hyperspectral imaging are described. In one implementation, a hyperspectral imaging system includes a sample holder configured to hold a sample, an illumination system, and a detection system. The illumination system includes a light source configured to emit excitation light having one or more wavelengths, and a first set of optical elements that include a first spatial light modulator (SLM), at least one lens, and at least one dispersive element. The illumination system is configured to structure the excitation light into a predetermined two-dimensional pattern at a conjugate plane of a focal plane in the sample, spectrally disperse the structured excitation light in a first lateral direction, and illuminate the sample in an excitation pattern with the one or more wavelengths dispersed in the first lateral direction.

A system comprising a light source, and a retention device configured to receive and retain a sample for measurement. The system includes a detector. An optical path couples light between the light source, the sample when present, and the detector. An optical objective is configured to couple light from the light source to the sample when present, and couple reflected light to the detector. A controller is configured to automatically control focus and/or beam path of the light directed by the optical objective to the sample when present. The detector is configured to output data representing a film thickness and a surface profile of the sample when present.

An arrangement for hyperspectral imaging, comprising an imaging sensor (170,270); a band-pass filter element (130,230): at least one imaging optics element (120,160,220,260) configured to form an image on the imaging sensor (170,270); and a first adjustable multi passband filter (150a,255); wherein the first (150a,255) adjustable multi passband filter is configured to be adjusted by tilting.

A hyperspectral detection system of luminescence from solid phase samples that are stimulated with radiation sources. includes an observation region, a sample holder configured to hold one or more solid-phase samples, at least one radiation source configured to irradiate the observation region, and a collector configured to collect the radiation emitted through or reflected by the sample upon irradiation by the at least one radiation source. The collector has a magnification factor value (M) equal to or lower than 20, and has a numerical aperture value equal to or higher than 0.25. A multichannel filter is configured to selectively filter the wavelength of the radiation collected by the collector, and an image sensor is configured to receive the filtered radiation and generate an image that is a two-dimensional map of the sample.

A hybrid spectral imager apparatus has an imaging head arrangement (IHA), a control and processing unit (CPU), and a display. The IHA includes an optical imager, multiband filtering optics (MBFO), and a sensor arrangement. The optical imager collects and focuses an image of a target scene or object along an imaging path. The multiband optics includes a beam divider for generating at least two replica images of the target image, and a multiband filter (MF) interposed into the imaging path and effecting multi-bandpass filtering in the image replicas. The sensor arrangement has at least one Mosaic filter array (MFA) focal plane array (FPA) sensor onto which the multiband filtered image replicas are focused, and a focal plane array masked, in a pixelized manner, with at least three wide-band primary color-type filters, with each primary color-type response separating and capturing one single-band. The CPU is coupled to the IHA and is configured to execute program instructions for calibrating image acquisition processes, controlling and synchronizing the acquisition/capturing of the image replicas by the MFA sensor arrangement, and spectrally purifying the MFA sensor arrangement responses to compensate band cross-talking between the MFA and the MF. The display is configured to display on a user interface at least the acquired single-band images. The CPU is further configured to reconstruct and display, on the display, a set of at least three different single-band images per MFA-FPA sensor employed. The IHA is configured to capture sets of different single-band images for video snapshot spectral imaging at desired spectral bands within the FPA sensor arrangement spectral sensitivity range.

A detection device, including a light emitting device, a light detection element, at least one reflective optical film element, and a control unit, is provided. The light emitting device is configured to provide an excitation beam. A part of the excitation beam whose main emission wavelength falls within an excitation wavelength range generates a fluorescence beam after irradiating onto the test specimen. The light detection element is configured to receive a part of the fluorescence beam whose main emission wavelength falls within a detection wavelength range. The control unit is coupled to at least one reflective optical film element and controls at least one reflective optical film element to filter out a part of a wavelength range of an incident beam. The incident beam is at least one of the excitation beam and the fluorescence beam. A detection method applicable to the detection device is also provided.

Imaging systems employing active illumination such as in-cabin monitoring or LiDAR systems may include a laser or LED source and an image sensor that is triggered by light reflecting off a target scene. The light has a spectral response that drifts as a function of temperature. To help compensate for such drifting in the spectral response of the light, a tiltable bandpass filter may be disposed over the image sensor. The bandpass filter is tilted or rotated using a filter tilting device. The filter tilting device may tilt or rotate the bandpass filter by an amount that causes a shift in the passband of the bandpass filter so that the shifted passband is aligned with the spectral response of the laser light across different ambient temperatures. Aligning the filter passband to the peak spectral response of the light source can help improve rejection of unwanted illumination from extraneous light sources.

Proposed is a spectroscope including a disperser configured to disperse incident signal light, wherein the disperser includes a bandpass filter configured to spectroscopically process the signal light by pivoting according to a driving signal and a light-receiving element configured to receive the signal light spectroscopically processed by bands and outputs a corresponding electrical signal.

A hybrid spectral imager apparatus has an imaging head arrangement (IHA), a control and processing unit (CPU), and a display. The IHA includes an optical imager, multiband filtering optics (MBFO), and a sensor arrangement. The optical imager collects and focuses an image of a target scene or object along an imaging path. The multiband optics includes a beam divider for generating at least two replica images of the target image, and a multiband filter (MF) interposed into the imaging path and effecting multi-bandpass filtering in the image replicas. The sensor arrangement has at least one Mosaic filter array (MFA) focal plane array (FPA) sensor onto which the multiband filtered image replicas are focused, and a focal plane array masked, in a pixelized manner, with at least three wide-band primary color-type filters, with each primary color-type response separating and capturing one single-band. The CPU is coupled to the IHA and is configured to execute program instructions for calibrating image acquisition processes, controlling and synchronizing the acquisition/capturing of the image replicas by the MFA sensor arrangement, and spectrally purifying the MFA sensor arrangement responses to compensate band cross-talking between the MFA and the MF. The display is configured to display on a user interface at least the acquired single-band images. The CPU is further configured to reconstruct and display, on the display, a set of at least three different single-band images per MFA-FPA sensor employed. The IHA is configured to capture sets of different single-band images for video snapshot spectral imaging at desired spectral bands within the FPA sensor arrangement spectral sensitivity range.