A projection system includes a light source unit, a spatial light modulation unit, and a projection optical system. Light source unit includes an optical fiber, a first light source part, and a second light source part. Optical fiber includes a light incident portion, a light emerging portion and a wavelength-converting portion. Wavelength-converting portion is disposed between light incident portion and light emerging portion. Wavelength-converting portion includes wavelength-converting elements. Wavelength-converting elements are able to be excited by excitation light to produce spontaneous emission of light having a longer wavelength than excitation light, and also excited by amplified spontaneous emission of light. First light source part makes excitation light incident on light incident portion. Second light source part makes seed light incident on light incident portion. Seed light causes wavelength-converting elements excited by excitation light or amplified spontaneous emission of light to produce stimulated emission of light.

A light source apparatus includes a first light source that includes a plurality of first light emitters arranged in a row along a first direction and emits a first luminous flux, a second light source that includes a plurality of second light emitters arranged in a row along a second direction and emits a second luminous flux in a direction in which the first luminous flux is emitted, and a combiner that combines the first and second luminous fluxes with each other to produce combined light and outputs the combined light to an irradiated region. The combined light has a combined light intensity distribution in which a first region where a light intensity of the first luminous flux is maximized and a second region where a light intensity of the second luminous flux is maximized do not overlap with each other.

A venous positioning projector includes an infrared light source module, a light splitting element, an infrared light image capture module, a processor, and a visible light projection module. The infrared light source module outputs a first infrared light to a target surface. The infrared light image capture module includes a filter and an infrared light image capture element. The light splitting element transmits a second infrared light reflected by the target surface to the filter. The infrared light image capture element receives the second infrared light passing through the filter. The processor generates venous image data according to the first infrared light and the second infrared light received by the infrared light image capture element. The visible light projection module generates a visible light based on the venous image data. The visible light is transmitted to the target surface through the light splitting element to generate a venous image.

An illuminator includes a light emitting apparatus which outputs first light belonging to a first wavelength band, a wavelength converter which converts part of the first light into second light belonging to a second wavelength band and causes the second and remainder of the first light to exit, a first optical system with positive power and which the first light enters, an optical element which the remaining first light enters and which reflects either the first or second light and transmits the other, a second optical system with positive power and which the first from the optical element and second light from the converter enter, a third optical system with positive power and causes the first light from the second optical system to enter the converter, and a fourth optical system with positive power and which the second light from the second optical system enters.

A light source apparatus according to an aspect of the present disclosure includes a light emitter that outputs first light, a wavelength conversion member that converts the first light into second light, an output section that outputs the second light, and a light collection member. The output section includes a first end section that faces the wavelength conversion member, a second end section that is located at the side opposite from the first end section along a center axis, and a tapering section that has a cross-sectional area that is perpendicular to the center axis and gradually decreases from the first end section toward the second end section, and the tapering section has a light output surface which inclines with respect to the center axis and via which the second light exits. The light collection member includes a third end section that is relatively close to the wavelength conversion member, a fourth end section that is located at the side opposite from the third end section, and a reflection surface that faces the light output surface and reflects the second light. At least a portion of the reflection surface of the light collection member, the portion facing the fourth end section, is separate from the light output surface at the side facing the second end section of the output section.

A light guiding unit of the present disclosure includes a light guiding member, an angle conversion member, and an adhesive. The light guiding member has an output end surface crossing longitudinal directions of the light guiding member and a side surface crossing the output end surface. The angle conversion member has an incident end surface entered by the light output from the output end surface. In a sectional view orthogonal to the output end surface, a dimension of the incident end surface is larger than a dimension of the output end surface. A part of the adhesive is provided between the output end surface and the incident end surface and another part of the adhesive is provided to cover a part of the side surface. In the sectional view orthogonal to the output end surface, a dimension of the adhesive provided to cover the part of the side surface is equal to or larger than the dimension of the output end surface and equal to or smaller than the dimension of the incident end surface, and the dimension of the adhesive is gradually larger from the side surface toward the incident end surface.

A display device includes a light source, a spatial light modulator (SLM), and an optical assembly that includes a first reflective surface and a second reflective surface that is opposite to the first reflective surface. The light source is configured to provide illumination light. The optical assembly is configured to receive the illumination light. At least a first portion of the illumination light received by the optical assembly is transmitted through the first reflective surface toward the second reflective surface, is reflected by the second reflective surface toward the first reflective surface, is reflected by the first reflective surface toward the second reflective surface, and is transmitted through the second reflective surface. The SLM is configured to receive and modulate the portion of the illumination light transmitted through the optical assembly, and to output the modulated light. A method performed by the display device is also disclosed.

A wavelength conversion element according to the present disclosure includes a substrate, a dichroic layer provided to a first surface of the substrate, an intermediate layer disposed so as to be opposed to the substrate via the dichroic layer, and a wavelength conversion layer disposed so as to be opposed to the dichroic layer via the intermediate layer, and configured to convert light in a first wavelength band into light in a second wavelength band. The dichroic layer has two or more types of refractive index layers having respective refractive indexes different from each other.

The application relates to the technical field of projection, and discloses a projection device which can improve the brightness of projection imaging. Part of the projection device comprises: an LED light source, a color wheel, a light-equalizing rod, a convex lens, a first Fresnel lens, an LCD panel and a projection lens; a ray of target light emitted by the LED light source emits a target alternating light through the color wheel, and the target alternating light comprises five monochromatic lights including red light, green light, blue light, yellow light and white light, and the five monochromatic lights enter the light-equalizing rod for uniform treatment to emit an uniform light spot, the uniform light spot is imaged at the first Fresnel lens through the convex lens, then irradiated into the LCD panel, and projected by the projection lens.

A projection image display device of the present disclosure includes a light source, an image forming element that forms an image, a color separating and combining unit that separates first illumination light and second illumination light, and combines first projection light and second projection light reflected by the image forming element, and a notch filter that is disposed between the light source and the color separating and combining unit. A first dichroic filter reflects the first illumination light and the first projection light. A first incident angle of the first illumination light with respect to the first dichroic filter is different from a second incident angle of the first projection light with respect to the first dichroic filter. The notch filter attenuates light in a first wavelength band including a boundary between a wavelength band of the first illumination light and a wavelength band of the second illumination light.