Abstract: An apparatus includes a plurality of cameras and a circuit. The cameras may be mounted on a vehicle and configured to generate a plurality of initial video signals of a scene outside of the vehicle. A plurality of fields of view of adjoining ones of the cameras may spatially overlap each other. The circuit may be configured to (i) store calibration values of the cameras generated during a calibration process, (ii) modify at least one of the initial video signals by applying the calibration values and (iii) generate a final video signal suitable to display to a user of the vehicle by stitching together the initial video signals. The calibration values may be used by the circuit to generate approximately continuous brightness within the scene in the final video signal.

Abstract: An inductor and a method for manufacturing same are provided. The method includes: bending two ends of a wound coil towards the same side; bending the two bent ends to respectively form contact sections at the tail ends, the two contact sections are located in the same plane; and encapsulating the coil in an encapsulation body, the two contact sections are exposed outside the encapsulation body.

Abstract: A conformal array antenna includes a substrate and a conductive circuit. The substrate has a non-conductive roughened curved surface formed with a plurality of hook-shaped structures that are formed by blasting a plurality of particles on the substrate. The non-conductive roughened curved surface defines a plurality of spaced-apart antenna pattern regions. The conductive circuit is located in the antenna pattern regions, and includes an activation layer formed on the roughened curved surface and containing an active metal, and a first metal layer formed on the activation layer.

Abstract: Methods of fabricating FinFET devices are provided. The method includes forming a fin over a substrate. The method also includes implanting a first dopant on a top surface of the fin and implanting a second dopant on a sidewall surface of the fin. The first dopant is different from the second dopant. The method further includes forming an oxide layer on the top surface and the sidewall surface of the fin, and forming a gate electrode layer over the oxide layer.

Abstract: A method for lithography patterning includes depositing a target layer over a substrate, the target layer including an inorganic material; implanting ions into the target layer, resulting in an ion-implanted target layer; forming a photoresist layer directly over the ion-implanted target layer; and exposing the photoresist layer to radiation in a photolithography process. The ion-implanted target layer reduces reflection of the radiation back to the photoresist layer during the photolithography process.

Abstract: A semiconductor device includes: at least one gate structure comprising a gate electrode over a substrate, the gate electrode comprising a conductive material; and a first dielectric layer disposed along one or more side wall of the at least one gate structure, the first dielectric layer comprising fluorine doped silicon oxycarbonitride or fluorine doped silicon oxycarbide.

Abstract: A method for making a conformal array antenna includes: providing a substrate having a non-conductive curved surface; roughening the curved surface; forming an activation layer containing an active metal on the roughened curved surface; forming a first metal layer on the activation layer by chemical plating process; and defining a plurality of spaced-apart antenna pattern regions on the first metal layer, by forming a gap along an outer periphery of each of the antenna pattern regions to isolate the antenna pattern regions from a remainder of the first metal layer. The curved surface is roughened by blasting a plurality of particles thereonto, or the spaced-apart antenna pattern regions are substantially evenly distributed.

Abstract: An optical member driving mechanism for driving an optical member having an optical axis is provided, including a fixed portion, a movable portion, a first elastic member, and a driving assembly. The movable portion is configured to hold the optical member, and is movably connected the fixed portion via the first elastic member. The driving assembly drives the movable portion to move along the optical axis within a range of motion. The range of motion includes a first limit moving range and a second limit moving range. The first limit moving range is the maximum distance that the movable portion can move toward the light-entering side, and the second limit moving range is the maximum distance that the movable portion can move toward the light-emitting side. When the movable portion is in a predetermined position, the first limit moving range is greater than the second limit moving range.

Abstract: A driving mechanism is provided and includes a holder, a frame, a resilient element and a first driving assembly. The holder includes a first holder surface for holding an optical element having an optical axis. The frame is movably connected to the holder and includes a first frame surface. The holder is movably connected to the frame through the first resilient element. The first driving assembly is adjacent to the holder and is used for driving the holder to move relative to the frame, wherein both the first holder surface and the first frame surface face the first resilient element and do not contact the first resilient element, and the shortest distance between the first holder surface and the first resilient element is different than the shortest distance between the first frame surface and the first resilient element.

Abstract: A driving system for moving several optical elements is provided, including a first module and a second module arranged in a first direction. The first module has a first terminal on a first side thereof to electrically connect to an external circuit. The second module has a second terminal on a second side thereof to electrically connect to the external circuit. The first and second sides are adjacent to each other and parallel to the first direction.

Abstract: A power management method includes: determining, by a control circuit, whether a first connector is connected to a first power supply and whether a second connector is connected to a second power supply. The method further includes: controlling, by the control circuit, a first conversion circuit to supply power to a battery unit and a system circuit, and computing a second fully-charged condition that is less than a first fully-charged condition when a determining result is yes. The method also includes: determining, by the control circuit, whether power information of the battery unit reaches the second fully-charged condition, and controlling, by the control circuit, a second conversion circuit to convert a second power from the second connector according to the second fully-charged condition, to supply power to the battery unit and the system circuit. A related circuit and electronic device are also provided.

Abstract: An optical module is provided, including a movable portion, a fixed portion and a driving assembly. The movable portion is used to hold an optical element having an optical axis. The movable portion is movably connected to the fixed portion. The driving assembly disposed in the fixed portion to drive the movable portion to move along the optical axis relative to the fixed portion. The driving assembly includes a first magnetic element and a second magnetic element. The first magnetic element and the second magnetic element are aligned along the optical axis. The size of the first magnetic element and the size of the second magnetic element along the optical axis are different.

Abstract: An optical module includes a first side and a second side, and includes a movable portion, a fixed portion, a driving portion, a position-sensing portion, and a circuit board. The movable portion includes a holder for holding an optical element with an optical axis. The fixed portion includes a base and a circuit component, wherein the circuit component has an external electrical connection portion, and the movable portion is movably connected to the fixed portion. The driving portion is configured to drive the movable portion to move relative to the fixed portion. The position-sensing portion includes a position-sensing element, and the position-sensing element is configured to sense the position of the movable portion relative to the fixed portion.

Abstract: Methods of fabricating FinFET devices are provided. The method includes forming a fin over a substrate. The method also includes implanting a first dopant on a top surface of the fin and implanting a second dopant on a sidewall surface of the fin. The first dopant is different from the second dopant. The method further includes forming an oxide layer on the top surface and the sidewall surface of the fin, and forming a gate electrode layer over the oxide layer.

Abstract: A method includes depositing a target layer over a substrate; reducing a reflection of a light incident upon the target layer by implanting ions into the target layer, resulting in an ion-implanted target layer; coating a photoresist layer over the ion-implanted target layer; exposing the photoresist layer to the light using a photolithography process, wherein the target layer reduces reflection of the light at an interface between the ion-implanted target layer and the photoresist layer during the photolithography process; developing the photoresist layer to form a resist pattern; etching the ion-implanted target layer with the resist pattern as an etch mask; processing the substrate using at least the etched ion-implanted target layer as a process mask; and removing the etched ion-implanted target layer.

Abstract: A method for forming a semiconductor device includes steps of: forming at least one gate structure comprising a gate electrode over a substrate, and forming a first dielectric layer of a first dielectric material along a side wall of the at least one gate structure. The first dielectric layer of the first dielectric material includes fluorine doped silicon oxycarbonitride with a doping concentration of fluorine. The dielectric constant of the first dielectric layer is adjusted through the doping concentration of fluorine.

Abstract: A two-speed transmission having two clutches for an electric vehicle includes an electric motor, a middle shaft, a first clutch, a second clutch, a first gear assembly and a second gear assembly. The electric motor includes a spindle. The first and second clutches are furnished on the middle shaft coaxially. The first gear assembly is furnished on the spindle and the first clutch respectively to generate a first gear ratio. The second gear assembly is furnished on the spindle and the first clutch respectively to generate a second gear ratio different from the first gear ratio. When the first clutch is activated to connect with the middle shaft, the second clutch separates from the middle shaft, and the electric motor outputs a first torque corresponding to the first gear ratio to the middle shaft. Similarly, the electric motor outputs a second torque corresponding to the second gear ratio.

Abstract: An apparatus includes a plurality of cameras and a circuit. The cameras may be mounted on a vehicle and configured to generate a plurality of initial video signals of a scene outside of the vehicle. A plurality of fields of view of adjoining ones of the cameras may spatially overlap each other. The circuit may be configured to (i) store calibration values of the cameras generated during a calibration process, (ii) modify at least one of the initial video signals by applying the calibration values and (iii) generate a final video signal suitable to display to a user of the vehicle by stitching together the initial video signals. The calibration values may be used by the circuit to generate approximately continuous brightness within the scene in the final video signal.

Abstract: A digital masking system includes a supporting structure for supporting a material, and a pattern imaging apparatus. The pattern imaging apparatus includes a light source device, multiple imaging devices that convert light from the light source device into a plurality of light beams each representing an image, and a combiner that combines the light beams into a single light beam which is projected toward a material.

Abstract: A method includes depositing a target layer over a substrate; reducing a reflection of a light incident upon the target layer by implanting ions into the target layer, resulting in an ion-implanted target layer; coating a photoresist layer over the ion-implanted target layer; exposing the photoresist layer to the light using a photolithography process, wherein the target layer reduces reflection of the light at an interface between the ion-implanted target layer and the photoresist layer during the photolithography process; developing the photoresist layer to form a resist pattern; etching the ion-implanted target layer with the resist pattern as an etch mask; processing the substrate using at least the etched ion-implanted target layer as a process mask; and removing the etched ion-implanted target layer.