Context recognition methods and apparatus are provided for an application processor and a micro control unit. It is determined whether an operation switch condition for switching to a sleep mode is satisfied. A request for execution of a context recognition function is sent to a micro control unit, when the operation switch condition is satisfied. The application processor switches to the sleep mode, when the context recognition function is executed by the micro control unit. The micro control unit collects sensor data at previously stored time intervals, and previously stored state information is updated based on the sensor data.

A communications device and network may collaborate to conserve battery life. The communications device may provide battery life status when attaching to a network. And the network may adjust treatment of the communications device depending upon the status.

Disclosed is a novel system and method for maintaining computing functionality when a client device must be used in a low-power state. More particularly, when a client device is placed in a low-power state, sleep mode, or even shut-down, this method transfers aspects of the machine state onto a virtual machine in the cloud. This virtual machine may then function as a partial or full emulator of the user's client machine and thus can be: 1) accessed; and 2) communicated with by the machine's owner or others who use the machine. As long as the client device is shutdown, the cloud continues to temporarily function as the user's machine. Numerous embodiments are disclosed including a “hybrid decomposition feature” in which the data on the client machine is prioritized and then transfer to a server, typically a virtual emulator, component by component or piecemeal manner or manner.

A method, of operating an end node to wirelessly communicate with a central node, includes: receiving wirelessly a current instance of a beacon signal periodically-transmitted from the central node; measuring a received power, P.sub.B-RX, of the beacon signal; reading locally-stored values of P.sub.B-TX and G representing a presumed transmitted power of the beacon signal and a performance goal of the end node, respectively; determining, for a given channel, a path loss, PL, based on the P.sub.B-RX and the P.sub.B-TX; and adaptively setting an energy level, E.sub.N-TX, of a forthcoming message to be transmitted from the end node by adaptively determining, based on PL and G, at least two of: a level of power, P.sub.N-TX; a forward error correction coding rate, c; and a spreading factor, SF; and a modulation format, M.

Techniques are disclosed relating to wireless transmission energy budgets. In some embodiments, an apparatus is configured to determine wireless transmission energy budget for a plurality of time periods. In some embodiments, the apparatus determines budget differently depending on whether it is in a thermal mode or a peak power mode. In some embodiments, the apparatus blanks scheduled wireless transmissions that intersect with the battery signal. In some embodiments, for a time interval subsequent to assertion of the battery signal, the apparatus operates in the peak power mode and determines energy budget for periods based on an amount of energy used for wireless transmissions in a most recent period in which transmissions were blanked in response to the battery signal. In some embodiments, in the thermal mode, the energy budget is based on thermal information for the apparatus, but may also allow carryover of unused budget from previous periods.

A system and method of providing status updates to one or more mobile devices. The method includes receiving a vehicle action request from the mobile device at a central office, determining a status update frequency based upon at least one real-time characteristic, and instructing the mobile device to request status updates on the vehicle action request to the central office at the status update frequency. In an alternative method, a plurality of mobile devices may be instructed to use different status update frequencies. The system includes a server configured to receive a vehicle action request from the mobile device at a central office, determine a status update frequency based upon at least one real-time characteristic, and instruct the mobile device to request status updates on the vehicle action request to the central office at the status update frequency.

Various embodiments provide systems and methods for encouraging progress toward a lower level of monitoring for a monitored individual.

Security is enhanced for a user of a mobile communications device by monitoring and controlling resource usage. First information associated with each of a plurality of mobile communications devices is collected, including configurations and settings for applications, components, resources and external resources for each mobile communications device. The collected information is used to identify an application, component, resource or external resource that is currently active on two of the mobile communications devices. Second information is transmitted to the first of the two mobile communications devices to reduce or terminate usage of the identified application, component, resource or external resource on the first mobile communications device.

The embodiments are directed to methods and systems for sending and receiving signals between one or more peripheral devices connected to a dongle system and an operating system. The methods and systems can detect when a dongle system has been connected to a mobile computing device. The methods and systems can receive an input to use the dongle system with a local operating system or a remote operating system. The methods and systems can also establish a communication channel between the local operating system and the remote operating system, and exchange signals between the dongle system and the remote operating system using one or more virtual filters.

The disclosed technology includes systems and methods for optimizing network traffic management in a mobile network. One method includes determining if a mobile application executing on a mobile device is associated with network signaling requiring a corresponding radio connection. At least a portion of the network signaling caused by the transactions is filtered. The filtered network signaling does not cause a corresponding radio connection. A signaling efficiency is calculated that indicates a total number of the radio connections that are saved as a result of the filtering.