Abstract: The present invention provides an atomizing system and device having a single authentication mechanism. The system includes at least one atomizing drug container and an atomizing device. The at least one atomized medicine container associates with an authentication code carrier and contains the atomized medicine. The atomizing device includes an atomizing module, a first power module, a control unit, an antenna module and an authentication module. The authentication module is configured to perform an authentication operation associated with the authentication code carrier to determine the authenticity of the at least one atomized medicine container or the atomized medicine and to generate an authentication result signal correspondingly.

Abstract: An atomization device and a cleaning method thereof are provided. The atomization device includes a jar portion and a host device. The jar portion is movably assembled with the host device and includes a nozzle portion and a container portion. The nozzle portion communicates with the container portion and is provided with an atomizer disposed therein. The atomizer is coupled to the host device. The cleaning method includes the steps of: assembling the jar portion and the host device and turning on the host device; determining whether the container portion contains a liquid; entering a safe mode if the container portion does not contain the liquid or determining whether the nozzle portion contains the liquid if the container portion contains the liquid; and entering an atomization mode if the nozzle portion does not contain the liquid or entering a cleaning mode if the nozzle portion contains the liquid.

Abstract: A slide rail assembly includes a rail, a moving rail, and a damping device. When the moving rail is moved relative to the rail, the damping device is pushed by the moving rail to provide damping effect.

Abstract: The present disclosure provides one embodiment of a semiconductor processing apparatus. The semiconductor processing apparatus includes a load lock designed to receive a wafer carrier; an inner wafer carrier buffer configured to hold the wafer carrier received from the load lock and to perform a nitrogen purge to the wafer carrier; and a processing module designed to perform a semiconductor process to wafers from the wafer.

Abstract: An optical system may include a lens assembly that has two or more single-sided wafer level optics (WLO) lenses arranged to propagate light. The optical system can further include an image sensor, wherein the lens assembly is arranged relative to the image sensor to propagate light received at a first surface of the lens assembly, through the two or more single-sided WLO lenses and to the image sensor. In some embodiments, the optical system further includes a camera which includes the lens assembly and the image sensor. In various embodiments, a smart phone, a tablet computer, or another mobile computing device may include such a camera. In some embodiments, the at least two single-sided wafer level optics (WLO) lenses are each separated by a gap G, wherein the gap may be different between each of the single-sided lenses, and the gap G may be zero.

Abstract: A method includes rotating a wafer, dispensing a liquid from a center of the wafer to an edge of the wafer to control a temperature of the wafer, and etching an etch layer of the wafer with an etchant during or after dispensing the liquid. The liquid is dispensed through a nozzle.

Abstract: A method for forming a semiconductor device is disclosed. A p-type field-effect transistor (p-FET) is formed on a semiconductor substrate. A dielectric layer is formed on the semiconductor substrate and completely covers the p-FET. At least an opening is formed in the dielectric layer and exposes a source/drain region of the p-FET. A conductive material is then formed filling the opening, wherein the conductive material comprises a first stress; specifically, a tensile stress between 400 and 800 MPa.

Abstract: A nebulizer assembly includes a nebulizer host and an auxiliary flow-guiding element. The auxiliary flow-guiding element is disposed on the nebulizer host. The auxiliary flow-guiding element has an auxiliary flow-guiding channel and at least one auxiliary bottom flow-guiding opening communicating with the auxiliary flow-guiding channel, and the auxiliary bottom flow-guiding opening penetrates through a bottom portion of the auxiliary flow-guiding element. A nebulized fluid generated by the nebulizer host can be sent to the auxiliary flow-guiding channel of the auxiliary flow-guiding element, and an outside air can pass through the auxiliary bottom flow-guiding opening and flow into the auxiliary flow-guiding channel. Therefore, the nebulized fluid in the auxiliary flow-guiding channel can be propelled towards a direction away from the auxiliary bottom flow-guiding opening by the outside air flowing into the auxiliary flow-guiding channel through the auxiliary bottom flow-guiding opening.

Abstract: A nebulizer assembly includes a nebulizer host and a main flow-guiding element. The main flow-guiding element is disposed on the nebulizer host. The main flow-guiding element has a main flow-guiding channel and at least one main bottom flow-guiding opening communicating with the main flow-guiding channel, and the main bottom flow-guiding opening penetrates a bottom portion of the main flow-guiding element. A nebulized fluid generated by the nebulizer host can be sent to the main flow-guiding channel of the main flow-guiding element, and an outside air can be introduced into the main flow-guiding channel by passing through the main bottom flow-guiding opening. Therefore, the nebulized fluid in the main flow-guiding channel can be propelled towards a direction away from the at least one main bottom flow-guiding opening by the outside air flowing into the main flow-guiding channel through the main bottom flow-guiding opening.

Abstract: A method for fabricating p-type field effect transistor (FET) includes the steps of first providing a substrate, forming a pad layer on the substrate, forming a well in the substrate, performing an ion implantation process to implant germanium ions into the substrate to form a channel region, and then conducting an anneal process to divide the channel region into a top portion and a bottom portion. After removing the pad layer, a gate structure is formed on the substrate and a lightly doped drain (LDD) is formed adjacent to two sides of the gate structure.

Abstract: Various approaches described herein improve the quality of results when fusing depth maps to generate dynamic three-dimensional (“3D”) models, applying texture details to dynamic 3D models, or rendering views of textured, dynamic 3D models. For example, when fusing depth maps to generate a dynamic 3D model, a fusion component can also incorporate intrinsic color values for points of the dynamic 3D model, potentially making the dynamic 3D model more accurate, especially for areas in which depth values are not reliable or not available. As another example, when applying texture details, a rendering component can apply smoothed, viewpoint-dependent texture weights to texture values from different texture maps, which can reduce blurring and avoid the introduction of noticeable seams. As another example, a rendering component can apply special effects indicated by metadata to rendered views, thereby allowing a content provider to assert artistic control over presentation.

Abstract: A slide rail assembly includes a first rail, a second rail, a blocking structure and a locking member. The second rail is movable relative to the first rail. The blocking structure is mounted to the first rail. The locking member is movably mounted to the second rail and configured to abut against the blocking structure, in order to prevent the second rail from being moved relative to the first rail from a retracted position along an opening direction.

Abstract: A coaxial electromagnetic apparatus formed of at least one magnetic disk and at least one coil disk synchronously and relatively movable and staggered at intervals. The magnetic disk and the coil disk are respectively provided with at least one power-driven module and at least one power generation module. The power-driven modules are provided at the outermost diameters of the magnetic disk and the coil disk. The power generation modules are provided at the innermost diameters of the magnetic disk and the coil disk. A rotation speed of the magnetic disk is increased due to torque amplification and good magnetic current management of the power-driven modules, thereby achieving low power consumption and large thrust of the power-driven modules. The power generation modules generate high cutting frequency to increase power generated and meet the requirement for supplying power to the power-driven modules, thereby achieving autonomous power generation and a self-propelled motor.

Abstract: A slide rail assembly includes a first rail, a second rail, a mounting member, a third rail and a fourth rail. The mounting member includes a first part, a second part and a third part. The first and second parts are connected to the third parts and are respectively extended along different directions. The mounting member has a first side and a second side. The third rail is connected to the first part of the mounting member and located at the first side of the mounting member. The third rail is movable relative to the first rail. The fourth rail is connected to the second part of the mounting member and located at the second side of the mounting member. The second rail is movable relative to the fourth rail.

Abstract: A slide rail assembly includes a first rail, a second rail and a mounting member. The mounting member is arranged with a third rail and a fourth rail. Wherein, the third rail is movable relative to the first rail, and the second rail is movable relative to the fourth rail.

Abstract: A slide rail assembly includes a first rail, a second rail, a mounting member, a third rail, a fourth rail and an engaging member. The mounting member includes a first part, a second part and a third part. The first part and the second part are connected to the third part and respectively extended along different directions. The third rail is connected to the first part of the mounting member, and the third rail is movable relative to the first rail. The fourth rail is connected to the second part of the mounting member, and the second rail is movable relative to the fourth rail. The engaging member is movably mounted to the mounting member. The engaging member is configured to allow the mounting member to be synchronously moved with the second rail along a predetermined direction.

Abstract: A display apparatus including a display panel and a driver circuit is provided. The display panel includes a display region and a non-display region. The non-display region includes a plurality of dummy pixels connected to one another. The driver circuit provides gate driving voltages and a test data voltage, so as to make the dummy pixels connected to one another generate a charging rate test signal in response to the test data voltage.

Abstract: A slide rail assembly includes a first rail, a second rail and a third rail. The second rail is movably mounted between the first rail and the third rail. The second rail and the third rail are movable relative to the first rail. The second rail and the third rail are detachable from the first rail.

Abstract: A light-emitting device is disclosed which includes a segmented active layer disposed between a segmented conductivity layer and a continuous conductivity layer, the active layer, the segmented conductivity layer, and the continuous conductivity layer being arranged to define a plurality of pixels, each pixel including a different segment of the segmented conductivity layer and the segmented active layer. A continuous wavelength converting layer disposed on the continuous conductivity layer is provided. A plurality of first contacts, each first contact being electrically connected to a different segment of the segmented conductivity layer is provided. One or more second contacts that are electrically connected to the continuous conductivity layer are also provided, the number of second contacts being less than the number of first contacts.

Abstract: A device may include a metal contact between a first isolation region and a second isolation region on a first surface of an epitaxial layer. The device may include a first sidewall and a second sidewall on a second surface of the epitaxial layer distal to the first isolation region and the second isolation region. The device may include a wavelength converting layer on the epitaxial layer between the first sidewall and the second sidewall.