Abstract: A 3D color image sensor and a 3D optical imaging system including the 3D color image sensor are provided. The 3D color image sensor includes a semiconductor substrate, having a plurality of first photodiodes and a plurality of second photodiodes, and a wiring layer formed under the first photodiodes and the second photodiodes. A light filter array layer is disposed on the first and the second photodiodes, having a plurality of color filter patterns and infrared (IR) light filter patterns, wherein each of the IR light filter patterns receives depth information of 3D color image of an object and corresponds to the first photodiode, and each of the color filter patterns receives color image information of 3D color image of the object and corresponds to the second photodiode.

Abstract: A light-emitting device (LED) chip is disclosed. The LED chip includes a body having a light extraction surface. The body includes semiconductor layers including an n-type region and a p-type region. A plurality of micro-lenses is directly on the light extraction surface of the body. A pair of bond pads is electrically connected to the n-type and p-type regions, respectively. A method for fabricating the LED chip and an LED package with the LED chip are also disclosed.

Abstract: A microlens array is provided, including a base layer with a plurality of first microlenses formed over a first region thereof, wherein the first microlenses are formed with a first height. A plurality of second microlenses are formed over a second region of the base layer, wherein the second region surrounds the first region and the second microlenses are formed with a second height lower than the first height. A plurality of third microlenses are formed over a third region of the base layer, wherein the third region surrounds the second and three regions, and the microlenses are formed with a third height lower than the first and second heights.

Abstract: An image sensor device is disclosed. The image sensor device includes a semiconductor substrate having a first pixel region and a second pixel region. A first photo-conversion device is disposed within the first pixel region of the semiconductor substrate to receive a first light source. A second photo-conversion device is disposed within the second pixel region of the semiconductor substrate to receive a second light source different from the first light source. The surface of the semiconductor substrate corresponding to the first photo-conversion device and the second photo-conversion device has a first microstructure and a second microstructure, respectively, permitting a reflectivity of the first pixel region with respect to the first light source to be lower than a reflectivity of the second pixel region with respect to the first light source. The invention also discloses a fabrication method of the image sensor device.

Abstract: Color filter arrays (CFA) and image sensors using same are provided. A color filter array includes a plurality of first color filter patterns respectively interlaced with a plurality of second color filter patterns, wherein the first and second color filter patterns comprise a plurality of color filters of at least three different colors of red (R), green (G) and blue (B) filters, and the first and second color filter patterns are not mirror symmetrical, and a blue (B) filter in one of the first color filter patterns is adjoined by a red (R) filter in one of the second color filter patterns adjacent thereto and/or a red (R) filter in one of the first color filter patterns is adjoined by a blue filter in one of the color filter patterns adjacent thereto.

Abstract: A method for designing a microlens array on a pixel array is disclosed. A radial distance of each pixel from a central pixel in a pixel array is calculated, in which the central pixel acts as an origin of an X-Y coordinate. A chief ray angle of each pixel is determined according to the corresponding radial distance. A microlens shift with respect to the corresponding pixel is determined according to the corresponding chief ray angle. Each microlens shift combines an X-axis direction shift with a Y-axis direction shift, and the X-axis direction shift ratio is different from the Y-axis direction shift ratio. A plurality of microlenses is arranged according to the corresponding microlens shifts to form a microlens array on the pixel array.

Abstract: A method for fabricating an image sensor device is disclosed. A substrate having a sensing area comprising a pixel array therein is provided. A photoresist layer is coated over the substrate. Exposure is performed on at least two regions of the photoresist layer by at least two binary half-tone masks, respectively, in which a first and second binary half-tone masks of the two binary half-tone masks have different optical transparency distributions. Development is performed on the exposed photoresist layer to form a convex microlens array corresponding to the pixel array of the sensing area and comprising at least two microlenses with different convex profiles.

Abstract: A microlens array is provided, including a base layer with a plurality of first microlenses formed over a first region thereof, wherein the first microlenses are formed with a first height. A plurality of second microlenses are formed over a second region of the base layer, wherein the second region surrounds the first region and the second microlenses are formed with a second height lower than the first height. A plurality of third microlenses are formed over a third region of the base layer, wherein the third region surrounds the second and three regions, and the microlenses are formed with a third height lower than the first and second heights.

Abstract: A light source device and projector using the same is provided. The light source device includes multiple light source modules and a multi-channel optical light tube. The multi-channel optical light tube includes multiple channels, each of which has a light guiding portion and corresponds to one or more of the light source modules. The light source module transmits the output light to the corresponding light channel, and the light guiding portion of each light channel is provided with a reflective surface for combining the light input through the light channels to the multi-channel optical light tube, thus providing the output of the light source device.

Abstract: A light-beam generator and a projecting system having the light-beam generator are proposed in the present invention. The light-beam generator includes an optical element and a light-emitting diode, wherein the optical element further includes a non-spherical reflecting curved surface which at least has a focus. Also, the light-emitting diode is located at the focus of the optical element for emitting light to the reflecting curved surface to form a light beam which is guided in a specific direction. By such arrangement, an output efficiency of light beams can be improved and a heat dissipation requirement can be reduced. Additionally, the light-beam generator proposed in the present invention can be applied to a projecting system having illuminant with specific polarized directions, so as to eliminate various prior-art drawbacks.

Abstract: A light source device and projector using the same is provided. The light source device includes multiple light source modules and a multi-channel optical light tube. The multi-channel optical light tube includes multiple channels, each of which has a light guiding portion and corresponds to one or more of the light source modules. The light source module transmits the output light to the corresponding light channel, and the light guiding portion of each light channel is provided with a reflective surface for combining the light input through the light channels to the multi-channel optical light tube, thus providing the output of the light source device.

Abstract: An illuminating device reusing polarized light uses an elliptical mirror, a cylindrical optical channel tube, a polarized light converter and at least two lenses to evenly distribute light and convert polarized light effectively. The incident end of the cylindrical optical channel tube is located at one focal point of the elliptical mirror. The emerging light from the cylindrical optical channel tube enters into the polarized light converter to form an image on the illuminated display panel.

Abstract: An illuminating device reusing polarized light uses an elliptic mirror, a cylindrical optical channel tube, a polarized light converter and at least two lenses to evenly distribute light and convert polarized light effectively. The incident end of the cylindrical optical channel tube is located at one focal point of the elliptic mirror. The emerging light from the cylindrical optical channel tube enters into the polarized light converter to form a image on the illuminated display panel.