Abstract: In aspects of RFID-based sensory monitoring of sports equipment, a number of RFID readers are positioned throughout a sports area to interrogate RFID tags that are associated with objects, such as sports equipment, used within the sports area. An object, such as a sports ball or protective equipment, can be set in motion along a trajectory within the sports area, and a RFID tag associated with the object receives an interrogation from the RFID readers positioned throughout the sports area. The object can include sensors integrated within a housing of the object, and the sensors are implemented to sense data about the motion and the trajectory of the object, as well as contact by the object with other objects. The sensed data is then communicated from the RFID tag of the object back to the one or more RFID readers that initiated the interrogation of the RFID tag.

Abstract: A method on an electronic device for a wireless network is described. A wireless signal is received from a second electronic device. A receive power level indication for the received wireless signal is determined. A path-loss offset for the received wireless signal is determined based on sensor data that indicates a path-loss condition. A path-loss for the received wireless signal is estimated based on the receive power level indication and the path-loss offset. A function is performed based on the path-loss and the path-loss threshold.

Abstract: A method facilitates establishment of wireless pairing connections between wireless electronic devices by: initiating, at a first device, a connection utility that enables the first device to establish a wireless connection with at least one second device; capturing an image of a selected second device, representing a second device to which a wireless connection is desired; and scanning for identifying information about each discoverable second device that is within a connection range of the first device. The method further includes: forwarding the captured image and any detected identifying information to a wireless connectivity assist (WCA) service; receiving wireless connection setup and configuration (WCSC) instructions from the WCA service; and establishing the wireless connection with the selected second device utilizing wireless connection setup and configuration (WCSC) instructions received from the WCA service.

Abstract: A method, device, system, or article of manufacture is provided for low-power management of multiple sensor chip architecture.

Abstract: A method, device, system, or article of manufacture is provided for low-power management of multiple sensor chip architecture.

Abstract: A method facilitates establishment of wireless pairing connections between wireless electronic devices by: initiating, at a first device, a connection utility that enables the first device to establish a wireless connection with at least one second device; capturing an image of a selected second device, representing a second device to which a wireless connection is desired; and scanning for identifying information about each discoverable second device that is within a connection range of the first device. The method further includes: forwarding the captured image and any detected identifying information to a wireless connectivity assist (WCA) service; receiving wireless connection setup and configuration (WCSC) instructions from the WCA service; and establishing the wireless connection with the selected second device utilizing wireless connection setup and configuration (WCSC) instructions received from the WCA service.

Abstract: A method, device, system, or article of manufacture is provided for low-power management of multiple sensor chip architecture. In one embodiment, a method comprises, at a computing device that includes a first processor, a second processor and a third processor, receiving, at the first processor, first sensor data from a first sensor; determining, at the first processor, a motion state of the computing device using the first sensor data; in response to determining that the motion state corresponds to a predetermined motion state, activating the second processor; receiving, at the second processor, second sensor data from a second sensor; determining, by the second processor, that the motion state corresponds to the predetermined motion state using the second sensor data; and, in response to determining that the motion state corresponds to the predetermined motion state using the second sensor data, sending the motion state to the third processor.

Abstract: A method includes a first wireless device initiating a wireless connection to a second wireless device and monitoring at least one context associated with one of the wireless connection and the second device. When contextual data is received that indicates a condition, the method further includes determining, based on a search of a firmware update service (FUS) database, whether a firmware update for the second wireless device is available within the FUS database. And when an available firmware update is received from the FUS database, the method includes triggering the first device to initiate the firmware update for the second device. The triggering of the first device to initiate the firmware update includes: transmitting a command to place the second device in firmware update mode; and forwarding the firmware update to the second device, such that the first device controls and/or initiates the firmware upgrade of the second device.

Abstract: A method facilitates establishment of wireless pairing connections between wireless electronic devices by: initiating, at a first device, a connection utility that enables the first device to establish a wireless connection with at least one second device; capturing an image of a selected second device, representing a second device to which a wireless connection is desired; and scanning for identifying information about each discoverable second device that is within a connection range of the first device. The method further includes: forwarding the captured image and any detected identifying information to a wireless connectivity assist (WCA) service; receiving wireless connection setup and configuration (WCSC) instructions from the WCA service; and establishing the wireless connection with the selected second device utilizing wireless connection setup and configuration (WCSC) instructions received from the WCA service.

Abstract: A method includes a first wireless device initiating a wireless connection to a second wireless device and monitoring at least one context associated with one of the wireless connection and the second device. When contextual data is received that indicates a condition, the method further includes determining, based on a search of a firmware update service (FUS) database, whether a firmware update for the second wireless device is available within the FUS database. And when an available firmware update is received from the FUS database, the method includes triggering the first device to initiate the firmware update for the second device. The triggering of the first device to initiate the firmware update includes: transmitting a command to place the second device in firmware update mode; and forwarding the firmware update to the second device, such that the first device controls and/or initiates the firmware upgrade of the second device.

Abstract: One disclosed method includes generating a rule set by an application running on a primary processor. The rule set specifies how the application handles events. The rule set is sent from the primary processor to a secondary processor and the primary processor is placed in sleep mode. The secondary processor may then handle at least one event corresponding to the application by executing the rule set while the primary processor is in sleep mode. In one embodiment, handling the event may include substituting for the application by the secondary processor by executing the rule set, and controlling a peripheral hardware device that is peripheral to the primary processor according to the rule set. Handling an event may also include waking the primary processor from sleep mode by the secondary processor and passing control back to the primary processor.

Abstract: A method on an electronic device for a wireless network is described. A wireless signal is received from a second electronic device. A receive power level indication for the received wireless signal is determined. A path-loss offset for the received wireless signal is determined based on sensor data that indicates a path-loss condition. A path-loss for the received wireless signal is estimated based on the receive power level indication and the path-loss offset. A function is performed based on the path-loss and the path-loss threshold.

Abstract: A method, device, system, or article of manufacture is provided for low-power management of multiple sensor chip architecture. In one embodiment, a method comprises, at a computing device that includes a first processor, a second processor and a third processor, receiving, at the first processor, first sensor data from a first sensor; determining, at the first processor, a motion state of the computing device using the first sensor data; in response to determining that the motion state corresponds to a predetermined motion state, activating the second processor; receiving, at the second processor, second sensor data from a second sensor; determining, by the second processor, that the motion state corresponds to the predetermined motion state using the second sensor data; and, in response to determining that the motion state corresponds to the predetermined motion state using the second sensor data, sending the motion state to the third processor.

Abstract: A method, device, system, or article of manufacture is provided for low-power management of multiple sensor chip architecture.

Abstract: A method, device, system, or article of manufacture is provided for low-power management of multiple sensor chip architecture.

Abstract: A method, device, system, or article of manufacture is provided for low-power management of multiple sensor chip architecture. In one embodiment, a method comprises, at a computing device that includes a first processor, a second processor and a third processor, performing, by the second processor, a first scan at a first scan rate for first location data using a sensor; receiving, at the second processor, from the sensor, the first location data; determining, by the second processor, a first location using the first location data; receiving, by the second processor, a modality of the computing device; in response to determining the first location, determining, by the second processor, that the modality corresponds to a predetermined state; and in response to determining that the modality corresponds to the predetermined state, performing, by the second processor, a second scan at a second scan rate for second location data using the sensor.

Abstract: A method for controlling subsidy locking of a handset device includes storing, in a handset device, an asymmetrically digitally signed subsidy unlock data block that has been modified based on a password after signing (505); modifying the stored unlock data block based on a received subsidy unlock password (510); and granting subsidy unlock status if the asymmetric digital signature of the modified, stored unlock data block properly verifies (510). A method (110) for controlling subsidy locking of a handset device includes storing, in the handset device, an asymmetrically digitally signed subsidy unlock data block that comprises a password portion that has been modified after signing (112); replacing the contents of the modified password portion with a received subsidy unlock password to produce an updated subsidy unlock data block (116); and granting subsidy unlock status if the asymmetric digital signature of the updated subsidy unlock data block properly verifies (118).

Abstract: A method for controlling subsidy locking of a handset device includes storing, in a handset device, an asymmetrically digitally signed subsidy unlock data block that has been modified based on a password after signing (505); modifying the stored unlock data block based on a received subsidy unlock password (510); and granting subsidy unlock status if the asymmetric digital signature of the modified, stored unlock data block properly verifies (510). A method (110) for controlling subsidy locking of a handset device includes storing, in the handset device, an asymmetrically digitally signed subsidy unlock data block that comprises a password portion that has been modified after signing (112); replacing the contents of the modified password portion with a received subsidy unlock password to produce an updated subsidy unlock data block (116); and granting subsidy unlock status if the asymmetric digital signature of the updated subsidy unlock data block properly verifies (118).