The illumination optical device includes a light source device and a homogenization device. The light source device includes a light source, a pair of multi-lenses having an incident side multi-lens and an exit side multi-lens, and configured to divide a light beam emitted from the light source into a plurality of first partial light beams, and an optical element on which the plurality of first partial light beams is superimposed, and which emits a diffused light beam. The homogenization device includes a pair of lens arrays having an incident side lens array and an exit side lens array, and dividing the diffused light beam into a plurality of second partial light beams, and a superimposing lens for superimposing the plurality of second partial light beams in the illumination target area.

The illumination optical device includes a light source device and a homogenization device. The light source device includes a light source, a pair of multi-lenses having an incident side multi-lens and an exit side multi-lens, and configured to divide a light beam emitted from the light source into a plurality of first partial light beams, and an optical element on which the plurality of first partial light beams is superimposed, and which emits a diffused light beam. The homogenization device includes a pair of lens arrays having an incident side lens array and an exit side lens array, and dividing the diffused light beam into a plurality of second partial light beams, and a superimposing lens for superimposing the plurality of second partial light beams in the illumination target area.

A novel imaging system is provided for capturing imaging data. According to the disclosed embodiments, the imaging system comprises one or more cameras configured to capture the same scene within each camera's field of view. The imaging system also includes a plurality of bandpass filters that may be positioned in front of one or more cameras. Each bandpass filter may allow the transmission of incident electromagnetic signals between different pairs of first and second wavelengths. Accordingly, when the bandpass filters are positioned in front of the one or more cameras, each camera captures a different spectral image, i.e., containing only certain frequency components of the same scene being imaged in the cameras. The bandpass filters may be selectively aligned with one or more cameras by rotating and/or translating the filters relative to the cameras' positions in the imaging system.

The present disclosure relates to a method and a device for correcting a color temperature of a flash lamp in the field of the computer technology. The method includes: obtaining a first color temperature value of a gray point region in a first image, in which the first image is obtained by capturing a scene when the flash lamp is closed; searching for an image region corresponding to the gray point region in a second image, in which the second image is obtained by capturing the scene when the flash lamp is open; and correcting the color temperature for the light compensation of the flash lamp according to a difference obtained by subtracting the first color temperature value from the second color temperature value.

The present disclosure relates to a method and a device for correcting a color temperature of a flash lamp in the field of the computer technology. The method includes: obtaining a first color temperature value of a gray point region in a first image, in which the first image is obtained by capturing a scene when the flash lamp is closed; searching for an image region corresponding to the gray point region in a second image, in which the second image is obtained by capturing the scene when the flash lamp is open; and correcting the color temperature for the light compensation of the flash lamp according to a difference obtained by subtracting the first color temperature value from the second color temperature value.

Light emitted from a light source is irradiated to a reflective light modulator which modulates irradiated light to reflect based on image data and the light reflected by the light modulator is projected. A ratio of return light returning from the light modulator to the light source to the light irradiated to the light modulator is calculated based on the image data. A light amount of the light emitted from the light source is calculated by using the calculated ratio and a detection output of an optical sensor provided between the light source and the light modulator.

Light emitted from a light source is irradiated to a reflective light modulator which modulates irradiated light to reflect based on image data and the light reflected by the light modulator is projected. A ratio of return light returning from the light modulator to the light source to the light irradiated to the light modulator is calculated based on the image data. A light amount of the light emitted from the light source is calculated by using the calculated ratio and a detection output of an optical sensor provided between the light source and the light modulator.

A first image display element modulates first illumination light in which red illumination light and infrared illumination light are alternately switched, based on an image signal for visible light image and an image signal for infrared light image, and emits first image light in which red image light and infrared image light are alternately switched. A second image display element modulates green illumination light based on a green image signal, and emits green image light. A third image display element modulates blue illumination light based on a blue image signal, and emits blue image light. A synthesizer synthesizes the first image light, the green image light, and the blue image light with one another, and obtains synthesized image light. A projection unit projects the synthesized image light.

A first projection display apparatus includes a color separator (41A) that has first and second incident surfaces (S1a and S1b), and allows light in first to third wavelength bands to pass therethrough or reflects the light in the first to third wavelength bands; first to third reflective light modulators (15); a first polarization splitter (12G); a second polarization splitter (12RB); and a projection optical system (19). Light in at least one of the first to third wavelength bands enters the first incident surface of the color separator as first polarized light, and light in the other wavelength bands enters the second incident surface of the color separator as second polarized light orthogonal to the first polarized light.

A first projection display apparatus includes a color separator (41A) that has first and second incident surfaces (S1a and S1b), and allows light in first to third wavelength bands to pass therethrough or reflects the light in the first to third wavelength bands; first to third reflective light modulators (15); a first polarization splitter (12G); a second polarization splitter (12RB); and a projection optical system (19). Light in at least one of the first to third wavelength bands enters the first incident surface of the color separator as first polarized light, and light in the other wavelength bands enters the second incident surface of the color separator as second polarized light orthogonal to the first polarized light.