A method for measuring the water concentration in a light-diffusing material, includes the following steps: an emission by N light sources of beams with wavelengths; an acquisition by M sensors, sensitive in at least one portion of the wavelengths; wherein M+N>3. The method also includes the steps of: calculating a first piece of information representing the diffusion, and a second piece of information representing the absorption, as a function of the signals and a piece of digital information representing the diffusing material as well as the sources and the sensors; calculating the water concentration in the sample as a function of the second piece of information.

An apparatus for interrogating a media to be analyzed, such as an avian egg, is provided. Such an apparatus includes an emitter assembly configured to emit light toward a media. The emitter assembly has a first emitter source configured to emit a first light signal and a second emitter source configured to emit a second light signal. The first and second light signals are transmitted through the media in phase quadrature. A detector assembly is configured to detect the first and second light signals transmitted through the media. The detector assembly is further configured to resolve a relative or absolute amplitude of each of the first and second light signals. A processor is configured to process the detected signal to identify a property of the media using at least one of the relative and absolute amplitudes of the first and second light signals. An associated method is also provided.

An apparatus (100) for optically characterizing a textile sample (106) comprises a presentation subsystem (102) comprising a viewing window (108). A radiation subsystem (114) comprises a radiation source (120) for directing a first, ultraviolet radiation (122) and a second, visible radiation (123) toward the sample (106), and causing the sample (106) to produce a fluorescent radiation (124) and a reflected radiation (125). A sensing subsystem (126) comprises an imager (130) for capturing the fluorescent radiation (124) and the reflected radiation (125) in an array of pixels (408). A control subsystem (132) comprises a processor (136) for controlling the presentation subsystem (102), the radiation subsystem (114), and the sensing subsystem (126), and for creating a fluorescent and reflected radiation image (400) containing both spectral information and spatial information in regard to the fluorescent radiation (124) and the reflected radiation (125).

A substance detection sensor includes a first light source, a second light source, and a substance detector. The first light source irradiates a detection area including a plurality of target areas with reference light having a first wavelength through surface irradiation using optical scanning. The second light source irradiates the detection area with first measuring light having a second wavelength different from the first wavelength through the surface irradiation using the optical scanning. The substance detector detects a specific substance in the detection area based on reflection light of the reference light from the first light source and reflection light of the first measuring light from the second light source.

A device for radiometrically gauging the surface of a measurement object (O) includes: at least one measurement array featuring an illumination array and a pick-up array; and a processor (P) for controlling the illumination array and the pick-up array and for processing measurement signals produced by the pick-up array and for providing processed image data. The illumination array exposes a region of the measurement object (O) to illumination light at an illumination angle (.sub.i) and an illumination aperture angle (.sub.i), and the pick-up array captures measurement light, reflected by the measurement object (O), at a pick-up angle (.sub.v) and a pick-up aperture angle (.sub.v) and guides it onto an image sensor exhibiting a pixel structure. The measurement object (O) is gauged multispectrally in multiple wavelength ranges, wherein the image sensor produces multispectral image data. Angular and spatial conditions are indicated which optimise the measurement device (MD) with regard to characterising sparkles.

An image processing apparatus includes a processor including hardware. The processor is configured to: acquire a first wavelength image and a second wavelength image, the first wavelength image being generated by irradiating a stage and by capturing light that has passed through the stage, the second wavelength image being generated by irradiating a specimen and by capturing light that has passed through the stage and the specimen, the specimen including a core tissue; calculate a spectral transmittance image; cause a display to display at least one of the spectral transmittance image and the second wavelength image as a display image; extract an area of the spectral transmittance image having spectral transmittance similar to spectral transmittance of a reference area in the display image as a core tissue area of the core tissue; and calculate an amount of the core tissue area.

A device for radiometrically gauging the surface of a measurement object (O) includes: at least one measurement array featuring an illumination array and a pick-up array; and a processor (P) for controlling the illumination array and the pick-up array and for processing measurement signals produced by the pick-up array and for providing processed image data. The illumination array exposes a region of the measurement object (O) to illumination light at an illumination angle (.sub.i) and an illumination aperture angle (.sub.i), and the pick-up array captures measurement light, reflected by the measurement object (O), at a pick-up angle (.sub.v) and a pick-up aperture angle (.sub.v) and guides it onto an image sensor exhibiting a pixel structure. The measurement object (O) is gauged multispectrally in multiple wavelength ranges, wherein the image sensor produces multispectral image data. Angular and spatial conditions are indicated which optimise the measurement device (MD) with regard to characterising sparkles.

An optical sensor device includes a light emitter for emitting, to a living body, lights having two wavelengths and blinking at a predetermined frequency, and a light receiver for receiving the lights from the living body. The light receiver outputs first and second detection signals corresponding to the respective wavelengths. A filter circuit extracts, from the first and second detection signals, modulation signals that are obtained with amplitude modulation of signals of the predetermined frequency. The modulation signals are amplified by a post-amplifier and are taken into an arithmetic processing unit after being converted to digital signals by an AD converter. The arithmetic processing unit calculates DC components and AC components of the first and second detection signals by employing the modulation signals converted the digital signals.

A dye measurement device includes: an illumination unit that radiates illumination light onto a specimen stained with three or more dyes; an image acquisition unit that captures transmitted light, transmitted through the specimen, of the illumination light radiated by the illumination unit, to obtain image signals; a narrow-band light generating unit that is disposed in the illumination unit or the image acquisition unit and that generates, with a switching manner, a plurality of narrow band light beams having different narrow bands in each of two or more different wavelength bands; and an image processing unit that determines an abundance ratio of the dyes through unmixing processing by using four or more of the image signals obtained when the image acquisition unit captures the narrow-band light beams generated by the narrow-band light generating unit.

An apparatus for interrogating a media to be analyzed, such as an avian egg, is provided. Such an apparatus includes an emitter assembly configured to emit light toward a media. The emitter assembly has a first emitter source configured to emit a first light signal and a second emitter source configured to emit a second light signal. The first and second light signals are transmitted through the media in phase quadrature. A detector assembly is configured to detect the first and second light signals transmitted through the media. The detector assembly is further configured to resolve a relative or absolute amplitude of each of the first and second light signals. A processor is configured to process the detected signal to identify a property of the media using at least one of the relative and absolute amplitudes of the first and second light signals. An associated method is also provided.