Abstract: Described is an apparatus which comprises: a backside of a first die having a redistribution layer (RDL); and one or more passive planar devices disposed on the backside, the one or more passive planar devices formed in the RDL.

Abstract: Processes, apparatuses, and systems associated with usage and contextual-based elevator operations management that have the capability to learn and to constantly adapt to usage patterns on a temporal basis through continuous monitoring of elevator journeys. An elevator journey may include a start and termination floor for an individual. Elevator journey data may be used to predict patterns of usage and maybe used, for example, to optimize the number of elevators operational at any time, determine the optimal parking position of each elevator, and/or determine an efficient allocation of elevators to groups or related floors.

Abstract: In an embodiment, a system includes voltage sensing logic to determine a first source voltage Vfirst source corresponding to a first source, and a controller to receive an indication of Vfirst source from the voltage sensing logic. The controller is to, responsive to Vfirst source>a first output voltage (V1), select a first source first regulator to input Vfirst source and provide V1; responsive to Vfirst source>a second output voltage (V2), select a first source second voltage regulator that inputs Vfirst source, and provide V2; responsive to Vfirst source?V1, select a second source first voltage regulator that inputs a second source voltage Vsecond source that corresponds to a second source and is substantially constant in time where Vsecond source>V1, and provide V1 independent of the first source first regulator and the first source second voltage regulator. Other embodiments are described and claimed.

Abstract: Described is an apparatus which comprises: a backside of a first die having a redistribution layer (RDL); and one or more passive planar devices disposed on the backside, the one or more passive planar devices formed in the RDL.

Abstract: Described is an apparatus which comprises: a backside of a first die having a redistribution layer (RDL); and one or more passive planar devices disposed on the backside, the one or more passive planar devices formed in the RDL.

Abstract: Embodiments of the present disclosure provide techniques and configurations for an orthotic device. In one instance, the device may include an orthotic device body and at least two sensors spatially disposed inside the orthotic device body. A first sensor may provide a first output responsive to pressure resulting from application of mechanical force to the orthotic device body. A second sensor may provide a second output responsive to flexing resulting from the application of mechanical force to the orthotic device body. The device may also include a control unit communicatively coupled with the sensors to receive and process the outputs provided by the sensors in response to pressure and flexing. Other embodiments may be described and/or claimed.

Abstract: Technologies for the sensing of biofeedback signals of a user include a body area network (BAN) system comprising one or more biofeedback sensors and one or more BAN controllers. The biofeedback sensors are configured to sense BAN signals, which may include biofeedback signals and body-coupled communication (BCC) signals. To facilitate communication, the biofeedback sensors may demultiplex the sensed BAN signals into biofeedback signals and incoming BCC signals. Similarly, the biofeedback sensors may multiplex outgoing BCC signals with sensed biofeedback signals. The BAN controller may communicate in a similar manner. Additionally, the BAN controller may process incoming BCC signals and provide feedback to the user based on BCC signals received from the biofeedback sensors.

Abstract: In at least one embodiment there is provided a method for managing bulk capacitance of a power supply system. The method includes precharging first and second bulk capacitors of the power supply system to approximately a first output voltage level and a second output voltage level, respectively; receiving a first command signal to generate, by the power supply, the first output voltage level; coupling the first bulk capacitance to load circuitry coupled to the power supply; receiving a second command signal to generate, by the power supply, the second output voltage level; and coupling the second bulk capacitance to the load circuitry coupled to the power supply.

Abstract: Processes, apparatuses, and systems associated with usage and contextual-based elevator operations management are disclosed herein. The operations management system may have the capability to learn and to constantly adapt to usage patterns on a temporal basis through continuous monitoring of elevator journeys. In embodiments, an elevator journey may include a start and termination floor for an individual. This data may be used to predict patterns of usage and maybe used, for example, to optimize the number of elevators operational at any time, determine the optimal parking position of each elevator, and/or determine an efficient allocation of elevators to groups or related floors. Other embodiments may be described and/or claimed.

Abstract: Described is an apparatus which comprises: a substrate; a plurality of holes formed as vias (e.g., through-silicon-vias (TSVs)) in the substrate; and a metal loop formed in a metal layer positioned above the plurality of holes such that a plane of the metal loop is orthogonal to the plurality of holes.

Abstract: A device to output two or more coordinated haptic effects, comprising, a first haptic effect generator to output a first haptic effect, a second haptic effect generator to output a second haptic effect and a processor to coordinate operation of the second haptic effect generator with operation of the first haptic effect generator based on an input provided to the processor.

Abstract: In an embodiment, a system includes voltage sensing logic to determine a first source voltage Vfirst source corresponding to a first source, and a controller to receive an indication of Vfirst source from the voltage sensing logic. The controller is to, responsive to Vfirst source>a first output voltage (V1), select a first source first regulator to input Vfirst source and provide V1; responsive to Vfirst source>a second output voltage (V2), select a first source second voltage regulator that inputs Vfirst source, and provide V2; responsive to Vfirst source?V1, select a second source first voltage regulator that inputs a second source voltage Vsecond source that corresponds to a second source and is substantially constant in time where Vsecond source>V1, and provide V1 independent of the first source first regulator and the first source second voltage regulator. Other embodiments are described and claimed.

Abstract: A method monitors the consumption of materials, including determining the presence of materials in a smart receptacle using a sensor located in the smart receptacle. A server is alerted when an actionable item is detected.

Abstract: A method monitors the consumption of materials, including determining the presence of materials in a smart receptacle using a sensor located in the smart receptacle. A server is alerted when an actionable item is detected.

Abstract: In at least one embodiment there is provided a method for managing bulk capacitance of a power supply system. The method includes precharging first and second bulk capacitors of the power supply system to approximately a first output voltage level and a second output voltage level, respectively; receiving a first command signal to generate, by the power supply, the first output voltage level; coupling the first bulk capacitance to load circuitry coupled to the power supply; receiving a second command signal to generate, by the power supply, the second output voltage level; and coupling the second bulk capacitance to the load circuitry coupled to the power supply.

Abstract: Technologies for the sensing of biofeedback signals of a user include a body area network (BAN) system comprising one or more biofeedback sensors and one or more BAN controllers. The biofeedback sensors are configured to sense BAN signals, which may include biofeedback signals and body-coupled communication (BCC) signals. To facilitate communication, the biofeedback sensors may demultiplex the sensed BAN signals into biofeedback signals and incoming BCC signals. Similarly, the biofeedback sensors may multiplex outgoing BCC signals with sensed biofeedback signals. The BAN controller may communicate in a similar manner. Additionally, the BAN controller may process incoming BCC signals and provide feedback to the user based on BCC signals received from the biofeedback sensors.

Abstract: Embodiments of the present disclosure provide techniques and configurations for an orthotic device. In one instance, the device may include an orthotic device body and at least two sensors spatially disposed inside the orthotic device body. A first sensor may provide a first output responsive to pressure resulting from application of mechanical force to the orthotic device body. A second sensor may provide a second output responsive to flexing resulting from the application of mechanical force to the orthotic device body. The device may also include a control unit communicatively coupled with the sensors to receive and process the outputs provided by the sensors in response to pressure and flexing. Other embodiments may be described and/or claimed.

Abstract: Embodiments described herein relate generally to monitoring a dining session using smart smallwares. A smart smallware may sense usage or non-usage associated with a dining session of a customer. Based on the sensed non-usage of the smart smallware, the smart smallware may detect a period of inactivity. In response to the detected period of inactivity, the smart smallware may transmit an indication of the detected period of inactivity. This transmitted indication may cause an external monitoring device to notify a waitperson that a customer associated with that smart smallware may require attention. Other embodiments may be described and/or claimed.

Abstract: A device to output two or more coordinated haptic effects, comprising, a first haptic effect generator to output a first haptic effect, a second haptic effect generator to output a second haptic effect and a processor to coordinate operation of the second haptic effect generator with operation of the first haptic effect generator based on an input provided to the processor.

Abstract: In accordance with various aspects of the disclosure, a method and apparatus for receiving multiple channels from a broadcast source and interfacing to multiple demodulators within a common silicon implementation is disclosed. A receiver apparatus is disclosed that may aggregate multiple channels output by multiple tuners into at least one composite signal. The at least one composite signal may be passed to a single ADC. The channels may then be extracted from the at least one composite signal in the digital domain prior to demodulation in separate demodulators.