Abstract: A carrier assembly for mounting equipment into a carrier slot includes an electro-magnetic interference (EMI) shield and an EMI finger. The EMI shield protects the mounted equipment from EMI. The EMI shield is formed in a first plane of the carrier assembly. The EMI finger protrudes from the EMI shield and is coupled to the EMI shield. The EMI finger is formed in a second plane perpendicular to the first plane. The EMI finger operates, when the carrier assembly is installed into the carrier slot, to couple the EMI shield to the carrier slot. The EMI finger, when viewed from a first direction that is perpendicular to both the first plane and the second plane, is formed in a tear-drop shape.

Abstract: A remote control system for gas detection and purification is disclosed and includes a remote control device, a gas detection module and a gas purification device. The remote control device includes a gas inlet and a gas outlet. The gas detection module is disposed in the remote control device and in communication with the gas outlet to detect the gas located in an indoor space. The gas detection module provides and outputs a gas detection datum, and the remote control device transmits an operation command via wireless transmission. The gas purification device is disposed in the indoor space and receives the operating instruction transmitted from the remote control device to be operated. When the gas purification device is under the activated state, the gas in the indoor space is purified, and the purification operation mode of the gas purification device is adjusted according to the first gas detection datum.

Abstract: A method of fabricating a semiconductor device includes forming a gate structure, a first edge structure and a second edge structure on a semiconductor strip. The method further includes forming a first source/drain feature between the gate structure and the first edge structure. The method further includes forming a second source/drain feature between the gate structure and the second edge structure, wherein a distance between the gate structure and the first source/drain feature is different from a distance between the gate structure and the second source/drain feature. The method further includes implanting a buried channel in the semiconductor strip, wherein the buried channel is entirely below a top-most surface of the semiconductor strip, a maximum depth of the buried channel is less than a maximum depth of the first source/drain feature, and a dopant concentration of the buried channel is highest under the gate structure.

Abstract: A gas detection purification device is disclosed and includes a main body, a purification unit, a gas guider, a gas detection module and a controlling-driving module. The main body includes an inlet, an outlet, an external socket and a gas-flow channel disposed between the inlet and the outlet. The purification unit is disposed in the gas-flow channel for filtering gas introduced through the gas-flow channel. The gas guider is disposed in the gas channel and located at a side of the purification unit. The gas is inhaled through the inlet, flows through the purification unit and is discharged out through the outlet. The gas detection module is plugged into or detached from the external socket. The controlling driving module is disposed within the main body and electrically connected to the gas guider to control the operation of the gas guider in an enabled state and a disabled state.

Abstract: An actuating and sensing module is disclosed and includes a bottom plate, a gas pressure sensor, a thin gas transportation device and a cover plate. The bottom plate includes a pressure relief orifice, a discharging orifice and a communication orifice. The gas pressure sensor is disposed on the bottom plate and seals the communication orifice. The thin gas transportation device is disposed on the bottom plate and seals the pressure relief orifice and the discharging orifice. The cover plate is disposed on the bottom plate and covers the gas pressure sensor and the thin gas-transportation device. The cover plate includes an intake orifice. The thin gas transportation device is driven to inhale gas through the intake orifice, the gas is then discharged through the discharging orifice by the thin gas transportation device, and a pressure change of the gas is sensed by the gas pressure sensor.

Abstract: A blood pressure detection device manufactured by a semiconductor process includes a substrate, a microelectromechanical element, a gas-pressure-sensing element, a driving-chip element, an encapsulation layer and a valve layer. The substrate includes inlet apertures. The microelectromechanical element and the gas-pressure-sensing element are stacked and integrally formed on the substrate. The encapsulation layer is encapsulated and positioned on the substrate. A flowing-channel space is formed above the microelectromechanical element and the gas-pressure-sensing element. The encapsulation layer includes an outlet aperture in communication with an airbag. The driving-chip element controls the microelectromechanical element, the gas-pressure-sensing element and valve units to transport gas.

Abstract: A blood pressure device includes a first blood pressure measuring device, a second blood pressure measuring device, and a controller. The first blood pressure measuring device is to be worn on a first position of a wrist so as to obtain a first blood pressure information of the first position. The second blood pressure measuring device is to be worn on a second position of the wrist so as to obtain a second blood pressure information of the second position. The controller is electrically coupled to the first blood pressure measuring device and the second blood pressure measuring device so as to adjust tightness between the expanders and the user's skin, respectively. The controller receives, processes, and calculates a pulse transit time between the first blood pressure information and the second blood pressure information, and the controller obtains at least one blood pressure value based on the pulse transit time.

Abstract: A semiconductor structure includes a first gate structure, a second gate structure coupled to the first gate structure, a source region, a first drain region, and a second drain region. The source region is surrounded by the first gate structure and the second gate structure. The first drain region is separated from the source region by the first gate structure. The second drain region is separated from the source region by the second gat structure. A shape of the first drain region and a shape of the second drain region are different from each other from a plan view.

Abstract: A method for assembling a component of a liquid crystal display device is introduced. An adhesion step is performed to adhere a flexible film to a substrate to form an assembled component by using an adhesion material covered over the overlapping area between the flexible film and the substrate. A plurality of air bubbles are trapped between the substrate and the flexible film by the adhesion material. To expel the air bubbles out of the assembled component, the assembled component is placed in an airtight chamber and a heating-pressurizing step is performed in the airtight chamber for properly raising the temperature of the assembled component and the air pressure within the airtight chamber.

Abstract: A method for assembling a component of a liquid crystal display device is introduced. An adhesion step is performed to adhere a flexible film to a substrate to form an assembled component by using an adhesion material covered over the overlapping area between the flexible film and the substrate. A plurality of air bubbles are trapped between the substrate and the flexible film by the adhesion material. To expel the air bubbles out of the assembled component, the assembled component is placed in an airtight chamber and a heating-pressurizing step is performed in the airtight chamber for properly raising the temperature of the assembled component and the air pressure within the airtight chamber.

Abstract: A method for assembling a component of a liquid crystal display device is introduced. Firstly, an adhesion step is performed to adhere a first part to a second part so as to form the component. Second, a heating-pressurizing step is performed in an airtight chamber for properly raising the temperature and the pressure of the airtight chamber to expel bubbles from the component.