Abstract: In a metrology sampling method, various index values that can detect various status changes of a process tool (such as maintenance operation, parts changing, parameter adjustment, etc.), and/or information abnormalities of the process tool (such as abnormal process data, parameter drift/shift, abnormal metrology data, etc.) appear in a manufacturing process are applied to develop an intelligent sampling decision (ISD) scheme for reducing sampling rate while VM accuracy is still sustained. The indices includes a reliance Index (RI), a global similarity index (GSI), a process data quality index (DQIX) and a metrology data quality index (DQIy).

Abstract: An integrated circuit for on-chip speed grading comprises test circuitry comprising scan chains and a test controller; and wide-range clock signal generation circuitry comprising phase-locked loop circuitry and frequency divider circuitry. The wide-range clock signal generation circuitry is configured to generate a wide-range test clock signal for the test circuitry to conduct a structural delay test for on-chip speed grading. The wide-range test clock signal is generated based on a test clock signal associated with the test circuitry, a frequency range selection signal and a frequency setting signal.

Abstract: A touch panel includes a substrate, a first electrode layer on a first surface of the substrate, and a second electrode layer on a second surface of the substrate. The first electrode layer has a plurality of first sensing lines configured to send touch signals and a plurality of first dummy lines coupled to the plurality of first sensing lines. The second electrode layer has a plurality of second sensing lines configured to receive the touch signals and a plurality of second dummy lines coupled to the plurality of second sensing lines. Each second dummy line defines at least one breaking point. Each first sense line has a projection at the second electrode layer which overlaps with one breaking point.

Abstract: A metal mesh structure capable of reducing breakpoint short circuits, including a plurality of first main channel wires, a plurality of second main channel wires, a plurality of first virtual wires and a plurality of second virtual wires. The first main channel wires are spaced apart and aligned in a first direction. The second main channel wires are spaced apart and aligned in a second direction. The second main channel wires cross the first main channel wires to form a plurality of main channel meshes. A method of manufacturing a metal mesh structure capable of reducing breakpoint short circuits is further provided. Given the aforesaid structure and method, the metal mesh is effective in reducing breakpoint short circuits.

Abstract: An electronic device, a controlling method thereof and a manufacturing method thereof are provided. The electronic device includes a substrate, a touch sensing circuit, a fingerprint identification module, a detection circuit and a processing unit. The touch sensing circuit is disposed on the substrate. The fingerprint identification module is disposed on the substrate. The detection circuit is disposed on the substrate. The detection circuit surrounds the fingerprint identification module to detect a sensing signal of a finger. The processing unit controls the fingerprint identification module according to the sensing signal.

Abstract: A method, an apparatus, and a system for migrating virtual machine backup information, which implement backup information migration after a virtual machine is migrated. The method includes: receiving, by a first backup server, a migration trigger message, where the migration trigger message carries pre-migration virtual-machine identification information and indication information of a second backup server; determining, by the first backup server, backup information of the virtual machine according to the pre-migration virtual-machine identification information; and sending, by the first backup server, the backup information to the second backup server. Therefore, the migrated virtual machine inherits backup information existing before the migration, such that the migrated virtual machine continues to be protected by backup data existing before the migration, and data of the virtual machine is backed up according to a backup policy existing before the migration.

Abstract: The present disclosure provides an acoustic wave fingerprint recognition unit including a sensor circuit substrate, a film adhesive layer positioned on the sensor circuit substrate, a piezoelectric material layer positioned on the film adhesive layer and a protection layer positioned on the piezoelectric material layer. The film adhesive layer is formed of a film adhesive material, and the film adhesive material is composed of a film adhesive agent and an organic solvent. The film adhesive agent is an epoxy resin, and the organic solvent is a C3-C8 and carbonyl-containing organic solvent. The solid content of the film adhesive agent in the film adhesive material is in a range of 1%-90%. A method for manufacturing the acoustic wave fingerprint recognition unit is also provided herein.

Abstract: Accessory device power management techniques are described in which a power exchange state for a system including a host computing device, an accessory device, and an adapter is recognized. Power exchange states may be defined according to relative states of charge (RSOC) and connection status for the system components and mapped to power management control actions. Responsive to the recognition of a current power exchange state, corresponding power management control actions may be ascertained and applied to jointly manage power for the system. For instance, the host device may draw supplemental power from a power source associated with an accessory device (e.g., a battery or power adapter) or supply power for use by the accessory device according to different states. Power exchanges may also be managed in accordance with capabilities of the accessory device identified based on authentication of the accessory device.

Abstract: A heat conductive plastic radiator and a communication device are provided. The communication device includes the heat conductive plastic radiator, a communication chip and an antenna. The heat of the communication chip is dissipated by the heat conductive plastic radiator. Along any direction, the heat conductive plastic radiator has a plurality of cross-sections perpendicular to the direction, and the plurality of cross-sections have different shapes. Therefore, one of the advantages of the heat conductive plastic radiator is that it less severely interferes with the antenna while efficiently dissipating heat.

Abstract: The description relates to enhancing user experience with devices, such as host and peripheral devices. One example relates to devices that can automatically power down when packaged for shipping and power up when opened by the user. Another example allows automatic, secure pairing between sets of host and peripheral devices without any affirmative user actions.

Abstract: Accessory device power management techniques are described in which a power exchange state for a system including a host computing device, an accessory device, and an adapter is recognized. Power exchange states may be defined according to relative states of charge (RSOC) and connection status for the system components and mapped to power management control actions. Responsive to the recognition of a current power exchange state, corresponding power management control actions may be ascertained and applied to jointly manage power for the system. For instance, the host device may draw supplemental power from a power source associated with an accessory device (e.g., a battery or power adapter) or supply power for use by the accessory device according to different states. Power exchanges may also be managed in accordance with capabilities of the accessory device identified based on authentication of the accessory device.

Abstract: An electrode component with electrode layers formed on intermediate layers includes a ceramic substrate, two intermediate layers formed on two opposite surfaces of the ceramic substrate, two electrode layers respectively formed on the two intermediate layers, two lead wires respectively connected to the electrode layers, and an insulating layer enclosing the ceramic substrate, the intermediate layers, the electrode layers, and portions of the two lead wires. The intermediate layer formed between the ceramic substrate and the electrode layer replaces the fabrication means for conventional silver electrode layer to provide good binding strength between the ceramic substrate and the electrode layer.

Abstract: A touch panel includes a substrate, plural conducting wires, an insulating layer, and a ground layer. The substrate includes an active region and a peripheral region surrounding the active region. The conducting wires are disposed in the peripheral region and extend along a first direction. The insulating layer is disposed on the conductive wires. The ground layer is disposed at an edge of the peripheral region and at least partially on the insulating layer, and the ground layer is at least partially in contact with the substrate.

Abstract: A portable electronic apparatus includes a first touch-sensing substrate, a camera module, transmission routes, a flexible printed circuit, and a main board. The first touch-sensing substrate has an active area and a peripheral area surrounding the active area. The camera module is connected to a second connecting area of the peripheral area. At least one of the transmission routes connects between a first connecting area and the second connecting area of the peripheral area, and rest of the transmission routes respectively connect between the active area and the first connecting area. The flexible printed circuit connects to the first connecting area. The flexible printed circuit includes a touch-sensor driver. The touch-sensor driver is electrically connected to at least part of the transmission routes. The main board includes a connector. The connector is connected with an end of the flexible printed circuit.

Abstract: A touch display apparatus includes a touch electrode structure and a display assembly. The touch electrode structure senses touch operations on the touch display apparatus. The display assembly displays images of the touch display apparatus. The display assembly includes a polarizer, a first substrate, a color filter, and a second substrate, arranged in that order. The touch electrode structure is sandwiched between the polarizer and the first substrate. The touch electrode structure comprises a first sensing electrode layer. The first sensing electrode is formed on a surface of the first substrate opposite to the color filter.

Abstract: Reversible connectors for accessory devices are described. In one or more implementations, a connector cable for an accessory of a host computing device is configured such that a head of the connector cable may be plugged into a corresponding port of the host in either orientation (straight or reverse). The host computing device is configured to sample signals associated with allocated pins of the connector to detect connection of the connector to an accessory port and to ascertain an orientation of the connector. A combination of high and low values of signals conveyed via these allocated pins upon insertion of the connector may be used by a controller of the host to distinguish between different types of devices and to resolve the orientation of the connector cable. A switching mechanism of the host computing device may then be configured to automatically route signals accordingly.

Abstract: A fingerprint identification device includes a fingerprint identification controller and a fingerprint identification sensor. The fingerprint identification sensor includes a substrate having a top surface, a bottom surface opposite to the top surface, and a side surface coupled between the top surface and the bottom surface. Sensor electrodes are arranged on the top surface, electrical leads couple the sensor electrodes and the fingerprint identification controller. The coupling leads extend from the top surface along the side surface to the bottom surface.

Abstract: A communication device integrally formed with antenna and mask is provided. The communication device comprises a circuit board, a frame, a communication chip and a mask. The frame is disposed on an upper surface of the circuit board. The frame has multiple sidewalls perpendicular to the upper surface and surrounding an opening. The communication chip is disposed on the upper surface and located in the opening. The mask is disposed on the circuit board, comprises a cover, multiple plates and an antenna module. The cover covers the communication chip. The plate is projected from a lower edge of the cover and parallel to the sidewalls, and has a hollowed area. The antenna module is connected to the hollowed area and integrally formed with the plate in one piece.

Abstract: An electrode component includes a ceramic substrate, two electrode layers formed on two opposite surfaces of the ceramic substrate, two pins respectively connected to the two electrode layers, and an insulating layer enclosing the ceramic substrate, the electrode layers and a portion of each pin. Each electrode layer is formed of two or more base metal materials or alloys thereof, and the concentrations of the base metal materials progressively vary across the electrode layer. Accordingly, the production cost is lowered, environmental pollution caused by evaporation and thermal dissolution of organic solvent can be prevented, risk of separable electrode interface at high-voltage discharge is mitigated, and the fabrication process of the electrode layer is shortened while maintaining bonding strength between the electrode layers and the ceramic substrate and solderability between the electrode layers and the pins.

Abstract: A multi-directional sensor includes a housing unit having a surrounding wall that defines a housing space, a first magnetic component disposed on the housing unit, a conductive body disposed in the housing space and magnetically attracted to the first magnetic component, and a plurality of spaced-apart electrically conductive terminals surrounding the conductive body. When the multi-directional sensor is subjected to an impact, the conductive body is forced to move toward two adjacent conductive terminals which are opposite to the direction of impact due to inertia so as to bridge and electrically interconnect the two adjacent conductive terminals so that a signal can be generated.