Abstract: According to various embodiments, a semiconductor device may include: a semiconductor substrate; a deep trench extending from a first portion of the semiconductor substrate to a second portion of the semiconductor substrate, wherein the second portion underlies the first portion; and an insulator region at least substantially lining sides of the deep trench. The insulator region includes at least one shallow trench in the first portion of the semiconductor substrate. At least a portion of the shallow trench(es) is arranged over at least a portion of the deep trench.

Abstract: The smart inflatable swimwear gets involved in the swimwear technology area. The smart inflatable swimwear is composed of the body, gasbags, air tubes, gas cylinder, gas needle, prober, bandages, power cord and caution light. The gasbags are mounted on both sides of the front side of the body of the described swimwear which also has gasbags on the middle of the back side. The gas cylinder is mounted on the body of the swimwear on the back side under the described gasbags. The described gas cylinder is connected to the gasbags on the back side through the air tube. The described gasbags on the back side are connected to the ones on the front side through the air tube.

Abstract: A method of establishing communication between an optical line terminal and an optical network unit within an optical access network includes receiving a signal indication from an optical transceiver of an optical line terminal. The signal indication includes: (i) a loss-of-signal indication indicating non-receipt of an upstream optical signal from the optical network unit; or (ii) a signal-received indication indicating receipt of the upstream optical signal from the optical network unit. The method includes determining whether the signal indication includes the loss-of-signal indication. When the signal indication includes the loss-of-signal indication, the method includes instructing the optical transceiver to cease signal transmission from the optical transceiver to the optical network unit.

Abstract: Semiconductor devices and methods of forming thereof are disclosed. A substrate with different device regions defined in the substrate is provided. A deep trench isolation (DTI) structure is formed in the substrate to isolate the different device regions. The DTI structure includes a fill material and a dielectric layer surrounding the fill material in the DTI structure. Local oxidation of the substrate is performed over the DTI structure to form a thermal dielectric layer which overlaps the DTI structure. The thermal dielectric layer which overlaps the DTI structure forms a thick top corner dielectric in the DTI structure.

Abstract: The present disclosure relates to semiconductor structures and, more particularly, to contact structures to deep trench isolation structures and methods of manufacture. The structure includes: a deep trench structure lined with insulator material on sidewalls thereof; conductive material filling the deep trench structure; a local oxide extending above the trench on exposed portions of the insulator material; an interlevel dielectric material on the local oxide and the conductive material filling the deep trench structure; and a contact in the interlevel dielectric material, extending to the conductive material and on a side of the local oxide.

Abstract: The present disclosure relates to semiconductor structures and, more particularly, to contact structures to deep trench isolation structures and methods of manufacture. The structure includes: a deep trench structure lined with insulator material on sidewalls thereof; conductive material filling the deep trench structure; a local oxide extending above the trench on exposed portions of the insulator material; an interlevel dielectric material on the local oxide and the conductive material filling the deep trench structure; and a contact in the interlevel dielectric material, extending to the conductive material and on a side of the local oxide.

Abstract: A method includes receiving user data packets from customer premises equipment (CPE) in communication with a network terminal over a communication link and enabling a network terminal-side loopback mode to establish a closed traffic test loop across the communication link between the network terminal and the CPE. The received user data packets indicate that a CPE-side loopback mode is enabled. The method also includes injecting a number of data bits into the closed traffic test loop until a saturation threshold of the communication link is satisfied, and when the number of data bits injected into the closed traffic test loop satisfies the saturation threshold, determining a packet error-rate of the number of data bits circulating in the closed traffic test loop. After determining the packet error-rate, the method also includes removing the closed traffic test loop across the communication link between the network terminal and the CPE.

Abstract: A method of establishing communication between an optical line terminal and an optical network unit within an optical access network includes receiving a signal indication from an optical transceiver of an optical line terminal. The signal indication includes: (i) a loss-of-signal indication indicating non-receipt of an upstream optical signal from the optical network unit; or (ii) a signal-received indication indicating receipt of the upstream optical signal from the optical network unit. The method includes determining whether the signal indication includes the loss-of-signal indication. When the signal indication includes the loss-of-signal indication, the method includes instructing the optical transceiver to cease signal transmission from the optical transceiver to the optical network unit.

Abstract: A configuration system may acquire updated configuration information corresponding to an underlying cloud platform affiliated with a hybrid cloud platform, the hybrid cloud platform being in communication with the underlying cloud platform. The updated configuration information may include network planning information and subnet planning information of the hybrid cloud platform. The configuration system may update previous configuration information corresponding to the underlying cloud platform with incremental data included in the updated configuration information. The configuration system may provision, based on the network planning information, a network for the underlying cloud platform. The configuration system may provision, based on the subnet planning information, a subnet for the underlying cloud platform.

Abstract: Semiconductor devices and methods of forming thereof are disclosed. A substrate with different device regions defined in the substrate is provided. A deep trench isolation (DTI) structure is formed in the substrate to isolate the different device regions. The DTI structure includes a fill material and a dielectric layer surrounding the fill material in the DTI structure. Local oxidation of the substrate is performed over the DTI structure to form a thermal dielectric layer which overlaps the DTI structure. The thermal dielectric layer which overlaps the DTI structure forms a thick top corner dielectric in the DTI structure.

Abstract: Embodiments of the present application disclose a user management method and apparatus of a hybrid cloud. The user management method of a hybrid cloud is performed by a management platform of the hybrid cloud. The method includes the steps of: obtaining user data in a role-based access control (RBAC) system; determining, according to a historical record, historical user data that has been distributed to a cloud platform in the hybrid cloud; obtaining incremental data of the user data relative to the historical user data; and sending the incremental data to the cloud platform in the hybrid cloud.

Abstract: A method of establishing communication between an optical line terminal and an optical network unit within an optical access network includes receiving a signal indication from an optical transceiver of an optical line terminal. The signal indication includes: (i) a loss-of-signal indication indicating non-receipt of an upstream optical signal from the optical network unit; or (ii) a signal-received indication indicating receipt of the upstream optical signal from the optical network unit. The method includes determining whether the signal indication includes the loss-of-signal indication. When the signal indication includes the loss-of-signal indication, the method includes instructing the optical transceiver to cease signal transmission from the optical transceiver to the optical network unit.

Abstract: A method of establishing communication between an optical line terminal and an optical network unit within an optical access network includes receiving a signal indication from an optical transceiver of an optical line terminal. The signal indication includes: (i) a loss-of-signal indication indicating non-receipt of an upstream optical signal from the optical network unit; or (ii) a signal-received indication indicating receipt of the upstream optical signal from the optical network unit. The method includes determining whether the signal indication includes the loss-of-signal indication. When the signal indication includes the loss-of-signal indication, the method includes instructing the optical transceiver to cease signal transmission from the optical transceiver to the optical network unit.

Abstract: A method includes receiving user data packets from customer premises equipment (CPE) in communication with a network terminal over a communication link and enabling a network terminal-side loopback mode to establish a closed traffic test loop across the communication link between the network terminal and the CPE. The received user data packets indicate that a CPE-side loopback mode is enabled. The method also includes injecting a number of data bits into the closed traffic test loop until a saturation threshold of the communication link is satisfied, and when the number of data bits injected into the closed traffic test loop satisfies the saturation threshold, determining a packet error-rate of the number of data bits circulating in the closed traffic test loop. After determining the packet error-rate, the method also includes removing the closed traffic test loop across the communication link between the network terminal and the CPE.

Abstract: A system and method for optimizing various vehicle safety systems, such as airbags and seat belt load tensioning limiters, for a particular occupant of a vehicle seat, such as the vehicle driver or passenger, based on the weight of the occupant and the fore-aft position of the seat. The method senses the mass of the occupant and the position of the seat and classifies the combination of the mass and position. The method then determines the optimized setting of the safety systems for that combination classification, and automatically sets the safety systems to that setting. The method can also determine the optimized setting of the safety systems based on whether the occupant is wearing a seat belt.

Abstract: A method for selecting a global positioning receiver includes receiving global positioning system signals from global positioning system receivers. The global positioning system receivers receive the global positioning system signals from corresponding global positioning system satellites. The method also includes replicating the global positioning system signals from the global positioning system receivers, determining a signal drift and a phase precision for each global positioning system signal, and selecting one of the global positioning system signals based on the corresponding signal drift and the phase precision of the global positioning system signal.

Abstract: A method for selecting a global positioning receiver includes receiving global positioning system signals from global positioning system receivers. The global positioning system receivers receive the global positioning system signals from corresponding global positioning system satellites. The method also includes determining a signal quality score of each received signal based on a signal drift and a phase precision of the corresponding signal, and selecting one of the received global positioning system signals having the highest signal quality score.

Abstract: A cascaded distribution framework includes a global positioning system receiver in communication with optical line terminals. Each global positioning system receiver receives a signal from a corresponding global positioning system satellite. Each optical line terminal includes a management card for each global positioning system receiver in communication with the optical line terminal and a line card. The management card receives a global positioning system signal from a corresponding global positioning system receiver. The line card is collocated for each management card in the optical line terminal. Each line card receives a global positioning system signal from each management card in the optical line terminal, determines a signal quality score of each received signal based on a signal drift and a phase precision of the corresponding signal, and selects one of the received global positioning system signals having the highest signal quality score.

Abstract: A system and method for optimizing various vehicle safety systems, such as airbags and seat belt load tensioning limiters, for a particular occupant of a vehicle seat, such as the vehicle driver or passenger, based on the weight of the occupant and the fore-aft position of the seat. The method senses the mass of the occupant and the position of the seat and classifies the combination of the mass and position. The method then determines the optimized setting of the safety systems for that combination classification, and automatically sets the safety systems to that setting. The method can also determine the optimized setting of the safety systems based on whether the occupant is wearing a seat belt.

Abstract: A signal distribution system includes global positioning system receivers in communication with optical line terminals and a system manager. Each global positioning system receiver receives a signal from a corresponding global positioning system satellite. Each optical line terminal includes a management card and a line card. The management card receives a signal from a corresponding global positioning system receiver. Each line card receives a signal from each management card and determines a signal drift and a phase precision for each signal. The system manager receives a failure communication for a global positioning system signal from a line card when the signal drift of the global positioning system signal is above a threshold signal drift or the phase precision of the signal is below a threshold phase precision. The system manager identifies a failure location of the signal within the system based on one or more received failure communications.