In a right-handed XYZ coordinate system, a dichroic-mirror array of the present disclosure includes a first group in which m (m≥2) dichroic mirrors DA1 to DAm are arranged parallel to each other along a positive direction of an X axis and a second group in which n (n≥2) dichroic mirrors DB1 to DBn are arranged parallel to each other along a negative direction of the X axis. Incident surfaces of the DA1 to DAm and incident surfaces of the DB1 to DBn are perpendicular to an XZ plane. A slope of straight lines with normal lines of the incident surfaces of the DA1 to DAm projected onto the XZ plane are negative, and a slope of straight lines with normal lines of incident surfaces of DB1 to DBn projected onto the XZ plane are positive.

The invention relates to an image sensor apparatus of a camera for detecting light. The image sensor apparatus comprises at least a first and a second sensor element and a carrier medium, wherein the carrier medium has a first and second input coupling region and a first and second output coupling region, wherein the first input coupling region has a first deflection structure which input couples light at a first given wavelength into the carrier medium in the direction of the first output coupling region, wherein the second input coupling region has a second deflection structure which input couples light at a second given wavelength into the carrier medium in the direction of the second output coupling region, wherein the first output coupling region has a first output coupling deflection structure which output couples the transmitted light from the carrier medium onto the first sensor element and wherein the second output coupling region has a second output coupling deflection structure which output couples the light onto the second sensor element.

Image data obtained by imaging of an imaging element capable of imaging a subject with sensitivity to a wavelength band of visible light and a wavelength band of near-infrared light via an optical system is acquired. A point image restoration process using a common restoration filter is performed on the image data of the subject captured with sensitivity to the wavelength band of the visible light by the imaging element and the image data of the subject captured with sensitivity to the wavelength band of the near-infrared light by the imaging element. The common restoration filter is calculated on the basis of average optical characteristics of the optical system obtained by performing weighted averaging of first optical characteristics with respect to the visible light of the optical system and second optical characteristics with respect to the near-infrared light of the optical system.

Disclosed herein, inter alia, are methods and systems of image analysis useful for rapidly identifying and/or quantifying features.

The invention provides an optical measurement device for measuring light to be inspected. The optical measurement device comprises a light receiving module, a light splitting module, and a plurality of color filters. The light receiving module is used for converting the light to be inspected into a first parallel light. The light splitting module is used for splitting the first parallel light into a plurality of parallel lights to be inspected. Each color filter receives at least one of the plurality of parallel lights to be inspected. The plurality of parallel lights to be inspected filtered by the plurality of color filters are used to calculate tristimulus values in the CIE color space.

A camera captures visual and infrared images through a single lens assembly by inserting a beam splitter along the path of light proceeding through the lens assembly to pass a first light spectrum to a first image sensor along the lens axis and reflect a second light spectrum to a second image sensor along a reflection axis. For example, a hot mirror reflects infrared light along the reflection axis and passes through visible light along the lens axis, and a cold mirror reflects visible light along the reflection axis and passes infrared light through along the lens axis. Processing of an infrared image to define boundaries of a visible image provides a high quality composite image.

A multispectral imaging device includes: an illumination optical system; and an imaging optical system, wherein the illumination optical system includes a filter group disposed in an overlap region of bundles of illumination rays which reach points in an imaging area of a subject, and including at least a first filter and a second filter having different transmission properties, and the imaging optical system includes: an image sensor which includes at least first light receiving elements and second light receiving elements; and a separation optical element which guides light which has passed through the first filter to the first light receiving elements, and guides light which has passed through the second filter to the second light receiving elements.

The present application discloses a confocal microscope including a light generator configured to simultaneously generate reflection light, which is reflected from a sample, and transmission light, which passes through the sample; a scanner configured to optically scan the sample and define a direction of a first optical path, along which the reflection light propagates; an adjuster configured to angularly adjust a direction of a second optical path, along which the transmission light propagates; a first signal generator configured to generate a first signal based on the reflection light; a second signal generator configured to generate a second signal based on the transmission light; and an image generator configured to generate a synthetic image in which a reflection image represented by the reflection light and a transmission image represented by the transmission light are synthesized in response to the first and second signals.

A color separation device changes a light path according to the wavelengths of incident light and an image sensor has improved light utilization efficiency by using the color separation device. The color separation device may include a first element having a first refractive index that varies according to wavelengths of light along a first refractive index distribution curve, and a second element having a second refractive index that varies according to wavelengths of light along a second refractive index distribution curve, the second refractive index distribution curve being different from the first refractive index distribution curve. The color separation device may be manufactured by simply joining two elements, namely, the first and second elements, together and thus may be more easily manufactured and perform more effective color separation.

A detection device (113) for a microscope comprises a dispersive element (211) in the beam path (290) of light and a selection element (212). The selection element (212) separates a beam path (291) of a spectral portion of the light from the beam path (290) of the light. The detector device (113) furthermore comprises a focusing optical unit (213) configured to focus the beam path (291) of the spectral portion of the light onto a sensor (214). By way of example, the microscope may be a confocal microscope.