Abstract: A semiconductor device includes a substrate, a dielectric layer disposed over the substrate, and an interconnect structure extending through the dielectric layer. The dielectric layer includes a low-k dielectric material which includes silicon carbonitride having a carbon content ranging from about 30 atomic % to about 45 atomic %. The semiconductor device further includes a thermal dissipation feature extending through the dielectric layer and disposed to be spaced apart from the interconnect structure.

Abstract: The head mounted display device includes a tube, a reflecting mirror, an infrared camera, and an imaging lens. The reflecting mirror is arranged in the tube. The reflecting mirror has a first plane and a second plane connected in sequence, wherein the first plane and the second plane have normal vectors that are not parallel to each other. The infrared camera receives the reflected image beam from the second plane of the reflecting mirror, wherein the second plane of the reflecting mirror receives the image beam to generate the reflected image beam. The imaging lens is arranged at the first open end of the tube.

Abstract: The head mounted display device includes a tube, a reflecting mirror, an infrared camera, and an imaging lens. The reflecting mirror is arranged in the tube. The reflecting mirror has a first plane and a second plane connected in sequence, wherein the first plane and the second plane have normal vectors that are not parallel to each other. The infrared camera receives the reflected image beam from the second plane of the reflecting mirror, wherein the second plane of the reflecting mirror receives the image beam to generate the reflected image beam. The imaging lens is arranged at the first open end of the tube.

Abstract: An optical lens adapted to be disposed on a transmission path of a light beam is provided. The optical lens includes a plurality of lenticular lens units extending along the same direction, and the lenticular lens units are disposed side by side along a direction perpendicular to the extension direction thereof, wherein each of the lenticular lens units has a height relative to a bottom surface of the optical lens, adjacent two of the lenticular lens units have a height difference D therebetween, and the optical lens satisfies D ? 2 ? ln ? ( 2 ) ? ? ? n ? ? 2 ?? , wherein n represents a refractive index of the optical lens, ? represents a central wavelength of the light beam, and ?? represents a spectral bandwidth of the light beam. In addition, an optical system and a method of manufacturing an optical lens are also mentioned.

Abstract: An optical lens adapted to be disposed on a transmission path of a light beam is provided. The optical lens includes a plurality of lenticular lens units extending along the same direction, and the lenticular lens units are disposed side by side along a direction perpendicular to the extension direction thereof, wherein each of the lenticular lens units has a height relative to a bottom surface of the optical lens, adjacent two of the lenticular lens units have a height difference D therebetween, and the optical lens satisfies D ? 2 ? ln ? ( 2 ) ? ? ? n ? ? 2 ?? , wherein n represents a refractive index of the optical lens, ? represents a central wavelength of the light beam, and ?? represents a spectral bandwidth of the light beam. In addition, an optical system and a method of manufacturing an optical lens are also mentioned.

Abstract: An optical base station including a base, a light source, a rotation plate and an optical fiber is provided. The light source is disposed on the base for providing a light beam. The rotation plate is disposed on the base. The optical fiber is disposed on the base and has an input end and a first output end. The rotation plate drives the optical fiber to rotate around a rotation axis. The rotation axis passes through the input end. The light beam enters the optical fiber from the input end and is output from the first output end after being transmitted in the optical fiber.

Abstract: An optical device includes a first optical component having a first optical axis and a second optical component having a second optical axis. The first optical component is mounted on the second optical component. No adhesive is between the first optical component and the second optical component. The first optical component has two opposite side surfaces which cover the second optical component and each have a row of laser welding spots formed thereon. A collimation error between the first optical axis and the second optical axis is not greater than 0.5 micrometer.