Abstract: A semiconductor device includes a bottom electrode; a magnetic tunneling junction (MTJ) element over the bottom electrode; a top electrode over the MTJ element; and a sidewall spacer abutting the MTJ element, wherein at least one of the bottom electrode, the top electrode, and the sidewall spacer includes a magnetic material.

Abstract: A fixing assembly for mounting UV lamps includes a base, a first gear and a plurality of mounting modules. The first gear is arranged on one side of the base; the mounting modules are arranged around the first gear. The mounting module includes a first driving assembly, a second driving assembly and a support frame. The first driving assembly is used to drive the second driving assembly and the support frame to move circumferentially around the first gear in a considerably horizontal plane, and the second driving component is used to drive the support to move back in a considerably vertical direction. The support frame is used for mounting UV lamp. The flexibility of the fixing assembly is improved. The UV lamp may comprehensively irradiate and cure the photosensitive adhesive.

Abstract: A sterilization apparatus for a portable electronic device including a cabinet and a carrier is provided. The carrier includes a base slidably disposed on the cabinet, multiple first positioning elements and multiple second positioning elements disposed in parallel on the base, multiple sterilization light sources corresponding to the second positioning elements and multiple pressure sensors disposed in parallel in the base. The base is configured to carry at least one portable electronic device. One second positioning element is disposed between any two adjacent first positioning elements, and any first positioning element and any second positioning element adjacent to each other are separated by a positioning space. The pressure sensors are respectively located in the positioning spaces. One sterilization light source is disposed between any two adjacent pressure sensors, and the pressure sensors are configured to sense a pressure from the portable electronic device.

Abstract: A method of making a ROM structure includes the operations of forming an active area having a channel, a source region, and a drain region; depositing a gate electrode over the channel; depositing a conductive line over at least one of the source region and the drain region; adding dopants to the source region and the drain region of the active area; forming contacts to the gate electrode, the source region, and the drain; depositing a power rail, a bit line, and at least one word line of the integrated circuit against the contacts; and dividing the active area with a trench isolation structure to electrically isolate the gate electrode from the source region and the drain region.

Abstract: A method of performing automatic tuning on a deep learning model includes: utilizing an instruction-based learned cost model to estimate a first type of operational performance metrics based on a tuned configuration of layer fusion and tensor tiling; utilizing statistical data gathered during a compilation process of the deep learning model to determine a second type of operational performance metrics based on the tuned configuration of layer fusion and tensor tiling; performing an auto-tuning process to obtain a plurality of optimal configurations based on the first type of operational performance metrics and the second type of operational performance metrics; and configure the deep learning model according to one of the plurality of optimal configurations.

Abstract: A distributed hearing system includes a plurality of near audio probe modules distributed at a plurality of specified locations in a specified area for recording audio information at the specified locations in the specified area, respectively; and a central data collecting/analysis/control module in communication with the plurality of near audio probe modules for collecting and analyzing the audio information from the plurality of near audio probe modules. The audio information is generated by a vehicle and includes a characteristic feature specific to the vehicle. A traffic control method is used with the distributed hearing system.

Abstract: A body mass index interval estimation device including an inertial sensor and an arithmetic circuit is provided. The inertial sensor is suitable for being worn on a body part to detect and obtain first gait information of a user in a traveling state. The first gait information includes first three-axis acceleration information and first three-axis angular velocity information. The arithmetic circuit causes processed first gait information after a pre-processing to pass an identification model to generate first body mass index interval information. The identification model is created by performing a training on a sample database. The sample database includes a plurality of second gait information and a plurality of label information corresponding thereto in a one-to-one manner. Each second gait information further includes second three-axis acceleration information and second three-axis angular velocity information.

Abstract: A distributed hearing system includes a plurality of near audio probe modules distributed at a plurality of specified locations in a specified area for recording audio information at the specified locations in the specified area, respectively; and a central data collecting/analysis/control module in communication with the plurality of near audio probe modules for collecting and analyzing the audio information from the plurality of near audio probe modules. The audio information is generated by a vehicle and includes a characteristic feature specific to the vehicle.

Abstract: A system for transforming sensed data is provided. The system includes an inertial sensor and a processor. The inertial sensor generates first sensed data by sensing a motion or behavior of a user. The processor is communicatively connected to the inertial sensor and pre-stores a data transformation model, wherein the data transformation model converts an acceleration vector and an angular velocity vector corresponding to the first sensed data into an acceleration vector and an angular velocity vector corresponding to second sensed data, and outputs the acceleration vector and the angular velocity vector corresponding to the second sensed data to an identification model pre-stored in the processor.

Abstract: A system for transforming sensed data is provided. The system includes an inertial sensor and a processor. The inertial sensor generates first sensed data by sensing a motion or behavior of a user. The processor is communicatively connected to the inertial sensor and pre-stores a data transformation model, wherein the data transformation model converts an acceleration vector and an angular velocity vector corresponding to the first sensed data into an acceleration vector and an angular velocity vector corresponding to second sensed data, and outputs the acceleration vector and the angular velocity vector corresponding to the second sensed data to an identification model pre-stored in the processor.

Abstract: In a system and a method for locating a mobile noise source, a sound sensing device catches a sound wave of the mobile noise source, and generates and stores a current sound characteristic information corresponding to the sound wave. An image pickup device catches an image of the mobile noise source, and generates and stores an entry of current image data corresponding to the mobile noise source. A spectrogram and image database stores entries of default spectrogram data and entries of default image data. An information processing unit compares the current sound characteristic information with the entries of default spectrogram data, and stores and associates the current sound characteristic information with the mobile noise source in the spectrogram and image database if no similarity between the current sound characteristic information and the entries of default spectrogram data reaches a preset value.

Abstract: A ceramic material for a multilayer ceramic capacitor has a capacitance variation from ?17 percent to +15 percent at a temperature ranging from ?55° C. to 200° C., and has a dielectric loss less than 1% at a temperature ranging from 90° C. to 200° C. The ceramic material includes a base component consisting of a barium titanate and a sodium bismuth titanate, and a manganese dopant in an amount not greater than 0.05 mole percent based on total moles of the base component.

Abstract: In a system for locating a mobile noise source, a sound sensing device catches a sound wave of a mobile noise source within a specified area for a specified time period, and outputs a characteristic information corresponding to the sound wave. An audio comparing device in communication with the sound sensing device compares the characteristic information with a set of standard data, and outputs an activating signal in response to a specific compared result. An image pickup device in communication with the audio comparing device performs an image pickup operation to catch an image of the mobile noise source in response to the activating signal.

Abstract: A ceramic material for a multilayer ceramic capacitor has a capacitance variation from ?17 percent to +15 percent at a temperature ranging from ?55° C. to 200° C., and has a dielectric loss less than 1% at a temperature ranging from 90° C. to 200° C. The ceramic material includes a base component consisting of a barium titanate and a sodium bismuth titanate, and a manganese dopant in an amount not greater than 0.05 mole percent based on total moles of the base component.

Abstract: In a system and a method for locating a mobile noise source, a sound sensing device catches a sound wave of the mobile noise source, and generates and stores a current sound characteristic information corresponding to the sound wave. An image pickup device catches an image of the mobile noise source, and generates and stores an entry of current image data corresponding to the mobile noise source. A spectrogram and image database stores entries of default spectrogram data and entries of default image data. An information processing unit compares the current sound characteristic information with the entries of default spectrogram data, and stores and associates the current sound characteristic information with the mobile noise source in the spectrogram and image database if no similarity between the current sound characteristic information and the entries of default spectrogram data reaches a preset value.

Abstract: In a system for locating a mobile noise source, a sound sensing device catches a sound wave of a mobile noise source within a specified area for a specified time period, and outputs a characteristic information corresponding to the sound wave. An audio comparing device in communication with the sound sensing device compares the characteristic information with a set of standard data, and outputs an activating signal in response to a specific compared result. An image pickup device in communication with the audio comparing device performs an image pickup operation to catch an image of the mobile noise source in response to the activating signal.