Abstract: A lens component 10 comprises K unit lenses 11, each extending in the X direction and having a common structure, arranged in parallel at a minimum period PL in the Y direction. Each unit lens 11 includes two partial lenses 121, 122 sectioned within the minimum period PL in the Y direction and a flat part 13 disposed between the partial lenses 121, 122. The partial lenses 121, 122 have respective optical axes different from each other but parallel to the Z direction and form images of a common point on an object surface onto an image surface A at respective positions different from each other.

Abstract: An optical component includes a multicore optical fiber and an I/O optical fiber. The multicore optical fiber has longitudinally extending cores within a common cladding. The cores are arranged on a circumference of a circle centered at a fiber axis in an end face of the multicore optical fiber. Both end faces of the multicore optical fiber are connected to each other such that the cores of the multicore optical fiber are optically connected to each other. Both end faces of the multicore optical fiber are adapted to rotate relative to each other about the fiber axis.

Abstract: A lens component 10 comprises K unit lenses 11, each extending in the X direction and having a common structure, arranged in parallel at a minimum period PL in the Y direction. Each unit lens 11 includes two partial lenses 121, 122 sectioned within the minimum period PL in the Y direction and a flat part 13 disposed between the partial lenses 121, 122. The partial lenses 121, 122 have respective optical axes different from each other but parallel to the Z direction and form images of a common point on an object surface onto an image surface A at respective positions different from each other.

Abstract: An optical component includes a multicore optical fiber and an I/O optical fiber. The multicore optical fiber has longitudinally extending cores within a common cladding. The cores are arranged on a circumference of a circle centered at a fiber axis in an end face of the multicore optical fiber. Both end faces of the multicore optical fiber are connected to each other such that the cores of the multicore optical fiber are optically connected to each other. Both end faces of the multicore optical fiber are adapted to rotate relative to each other about the fiber axis.

Abstract: An optical combiner in which fewer parts are used comprises an optical component and a plastic body. The component comprises: a first filter reflecting first light having a first wavelength and being transparent to second light having a second wavelength and third light having a third wavelength; a second filter reflecting second light and being transparent to third light; and a base transparent to second light and third light. The first filter and the second filter are provided on opposed surfaces of the base. The plastic body has first, second, and third surfaces, and the first surface provides first, second, and third lenses. The component is provided in the plastic body such that light from the first lens is connected to a path to the second surface through the first filter and light from the second lens is connected to the path through the second filter. The third surface is a reflecting surface for connecting light from the third lens to the path.

Abstract: An optical combiner in which the number of parts used is lessened is made of a resin. The optical component comprises a first surface, a diffraction grating, and a second surface. The first surface is a surface providing first, second, and third lenses. The diffraction grating diffracts to a common optical path leading to the second surface light of the first wavelength incident on the first lens, light of the second wavelength incident on the second lens, and light of the third wavelength incident on the third lens. The second surface emits light incident thereon through the common optical path. The optical path from the first surface to the diffraction grating and the common optical path are constituted of the resin.

Abstract: There is provided a light distribution control panel that can suppress reflection on a glass surface in a mobile unit when the light distribution control panel is applied to a display device mounted on the mobile unit, and a display device for mounting on a mobile unit in which the light distribution control panel is used. A light distribution control panel includes a base body serving as a plate-like or sheet-like base material made of a translucent material, and the base body has a plurality of convex portions for light distribution control formed on one surface opposite to the backlight side of the base body. The plurality of convex portions are positioned to extend in parallel to one another.

Abstract: An optical combiner in which the number of parts used is lessened is made of a resin. The optical component comprises a first surface, a diffraction grating, and a second surface. The first surface is a surface providing first, second, and third lenses. The diffraction grating diffracts to a common optical path leading to the second surface light of the first wavelength incident on the first lens, light of the second wavelength incident on the second lens, and light of the third wavelength incident on the third lens. The second surface emits light incident thereon through the common optical path. The optical path from the first surface to the diffraction grating and the common optical path are constituted of the resin.

Abstract: An optical combiner in which fewer parts are used comprises an optical component and a plastic body. The component comprises: a first filter reflecting first light having a first wavelength and being transparent to second light having a second wavelength and third light having a third wavelength; a second filter reflecting second light and being transparent to third light; and a base transparent to second light and third light. The first filter and the second filter are provided on opposed surfaces of the base. The plastic body has first, second, and third surfaces, and the first surface provides first, second, and third lenses. The component is provided in the plastic body such that light from the first lens is connected to a path to the second surface through the first filter and light from the second lens is connected to the path through the second filter. The third surface is a reflecting surface for connecting light from the third lens to the path.

Abstract: The present invention relates to an optical signal processor which can perform favorable optical signal processing even when there are environmental changes and the like. The optical signal processor inputs light emitted from an end face of an optical fiber, subjects the inputted light to processing according to its wavelength, and outputs the processed light so as to make it incident on the end face of the optical fiber; and comprises optical systems, a diffraction grating device, mirror reflectors, an optical path turning part, and a monitor part. The optical path turning part transmits therethrough a part of the incident light and reflects at least a part of the remnant. The optical system monitors the light transmitted through the optical path turning part.

Abstract: The optical multiplexer/demultiplexer 100 includes a member 110 on which optical waveguides 111 to 114 and a groove 115 are formed and an optical filter 120 inserted in the groove 115. The member 110 is a planar optical waveguide where the optical waveguides 111 to 114 are formed on one surface thereof, and the groove 115 is formed thereon. Before the groove 115 is formed, the optical wave guide 111 and the optical waveguide 114 are a continuous optical waveguide; and the optical waveguide 112 and the optical waveguide 113 are a continuous optical waveguide. A straight groove 115 is formed so as to go through an intersecting point of the two continuous optical waveguides. The optical waveguides 111 and 114 are formed straightly on the member 110.

Abstract: A DGD compensating apparatus capable of compensating the time varying DGD of each wavelength component in the propagation light. The DGD of each wavelength component in the inputted light is monitored by a DGD monitor, and a polarization splitter splits the inputted light into first polarization light and second polarization light orthogonal to each other. The first polarization light is de-multiplexed by de-multiplexer for each wavelength component, and the de-multiplexed wavelength components in the first polarization light are multiplexed by a multiplexer after being respectively added with delays by an optical delay. The first polarization light in which each wavelength component is added with the associated delay and the second polarization light are combined and thereafter being outputted by a polarization combiner.

Abstract: An optical system 111 collimates wavelength components of wavelengths ?1-?3 emerging from an end face of optical fiber 11, a diffraction grating 121 separates them by wavelength, and an optical system 112 condenses them. The component of the wavelength ?1 is focused at a focus position by the optical system 112 and diverges after the focus position. Then the component of the wavelength ?1 is collimated by an optical system 113, travels via a diffraction grating 122, and is condensed by an optical system 114 to enter an end face of optical fiber 22. The component of the wavelengths ?2, ?3 condensed by the optical system 112 are reflected by reflecting portions 132, 133 set at their respective focus positions, are collimated by the optical system 112, travel via the diffraction grating 121, and are condensed by the optical system 111 to enter an end face of optical fiber.

Abstract: An optical multiplexer/demultiplexer is provided with a first member, a second member and an optical filter. The first member is a planar waveguide and is formed with an optical waveguide and another optical waveguide. The second member is a planar waveguide and is formed with an optical waveguide and another optical waveguide. The optical filter is a dielectric multi-layered filter and is sandwiched between the end face of the first member and the end face of the second member.

Abstract: The present invention relates a variable optical multiplexer/demultiplexer which can be made smaller and can restrain characteristics from deteriorating. The optical multiplexer/demultiplexer comprises a first optical system, a wavelength branching device, a second optical system, and an optical path changing part. The optical multiplexer/demultiplexer has a plurality of input/output ports, and the first optical system, the wavelength branching device, and the second optical system are disposed between the ports and the optical path changing part. When light is fed into any of the ports, individual wavelength components included in the light are outputted from any of the ports. The optical path changing part inputs the wavelength components condensed by the second optical system, and output the wavelength components to an output optical path which is parallel to but not on the same line as the input optical paths of the wavelength components.

Abstract: The present invention relates to an optical device having a structure that can make the diameter of the emitted Gaussian beam smaller. The optical device is arranged between a first and second positions, and comprises a first and second optical systems separated with a focus on an intermediate position between the first and second positions. The first optical system, arranged between the first and intermediate positions, comprises a first light entrance surface on which a Gaussian beam having a beam waist, whose radius becomes w0 at the first position, is incident, and a first light emission surface from which a Gaussian beam having a beam waist, whose radius becomes w1 at the intermediate position, is emitted.

Abstract: [Problems to be solved] To provide an optical switching device which can switch between input/output optical paths of input/output ports while suppressing the influence on optical signals passing through other input/output ports. [Means to solve problems] An optical switching device comprises an optical switch array 6 for switching between input/output paths of a plurality of input/output optical fibers. The optical switch array 6 comprises a substrate 8, on which a cantilever 11 is supported. A part of the cantilever 11 on the leading end side is provided with an annular support 12, which supports a movable mirror 7 inclinably. The movable mirror 7 reflects an optical signal from any of the input/output optical fibers toward another input/output optical fiber. The leading end of the cantilever 11 is provided with a comb part 14.

Abstract: A movable mirror device comprises a deformable mirror; and a drive section for deforming the mirror into a concave shape and into a convex shape.

Abstract: A movable mirror device has a plurality of reflecting mirrors and a plurality of mirror drivers. The plurality of reflecting mirrors are reflecting mirrors to reflect signal light and are arranged in a one-dimensional direction along a predetermined plane. The plurality of mirror drivers are arranged two-dimensionally relative to the one-dimensional direction and individually drive the respective reflecting mirrors.

Abstract: An optical device has first and second non-parallel optical paths, and a light reflecting surface. The reflecting surface may have a first and second planar portion. The first planar portion receives light from the first path to reflect the light toward the second path. The second planar portion may form an angle ?1 with the first planar portion. Angle ?1 satisfies a condition of 175°??<180° in either clockwise or counterclockwise rotation from the first planar portion.