In embodiments of the present disclosure, after a mobile terminal recognizes a type of a power adapter, the mobile terminal transmits indication information to the power adapter. The indication information is configured to indicate that the mobile terminal has recognized the type of the power adapter and instruct the power adapter to activate a quick charging process. The power adapter then negotiates with the mobile terminal via the quick charging process to determine charging parameters, and charges a battery of the mobile terminal in a multi-stage constant current mode.

Multi-channel audio signal processing includes receiving a left stereo audio signal from a first channel and a right stereo audio signal from a second channel; up-mixing the left and the right stereo audio signals to generate an up-mixed audio signal for a third channel; de-correlating the up-mixed audio signal from the left and the right stereo audio signals to generate a de-correlated up-mixed audio signal; providing the left and right stereo signals and the de-correlated up-mixed audio signal to first, second, and third loudspeakers respectively to generate first, second, and third sound signals, respectively; picking up the first, second and third sound signals with a microphone to generate a microphone output signal; and adaptively filtering the microphone output signal with an acoustic echo canceller based on the left, the right, and the de-correlated up-mixed audio signal to generate an echo compensated microphone signal.

An integrated power-regulating charge system is an apparatus used to manage the flow of electrical power to the rechargeable battery of a connected electrical system. To accomplish this, the integrated power-regulating charge module includes an electrical input terminal, an output terminal, a shutoff switch, a microcontroller, and a wireless communication module. The electrical input terminal is used to connect the integrated power-regulating charge system to the power input terminal of the electrical system. The output terminal is used to transfer power from the integrated power-regulating charge system into the connected electrical system. The shutoff switch is electrically connected between the electrical input terminal and the output terminal and is used to open the circuit between these two components. The microcontroller directs the shutoff switch be opened or closed. The wireless communication module receives commands that are wirelessly transmitted to the microcontroller from external electrical systems.

An integrated power-regulating charge system is an apparatus used to manage the flow of electrical power to the rechargeable battery of a connected electrical system. To accomplish this, the integrated power-regulating charge module includes an electrical input terminal, an output terminal, a shutoff switch, a microcontroller, and a wireless communication module. The electrical input terminal is used to connect the integrated power-regulating charge system to the power input terminal of the electrical system. The output terminal is used to transfer power from the integrated power-regulating charge system into the connected electrical system. The shutoff switch is electrically connected between the electrical input terminal and the output terminal and is used to open the circuit between these two components. The microcontroller directs the shutoff switch be opened or closed. The wireless communication module receives commands that are wirelessly transmitted to the microcontroller from external electrical systems.

A computer-implemented method includes identifying critical data on a primary storage of a mobile device, where the primary storage is powered by a primary battery component. The critical data is backed up from the primary storage to a secondary storage. A charge level of the primary battery component is detected. It is determined that the charge level of the primary battery component is less than a minimum threshold. The mobile device is switched from a primary mode to a secondary mode, based on the charge level being less than the minimum threshold. A secondary battery component powers the secondary storage in the secondary mode, and the critical data is accessible on the secondary storage in the secondary mode.

A computer-implemented method includes identifying critical data on a primary storage of a mobile device, where the primary storage is powered by a primary battery component. The critical data is backed up from the primary storage to a secondary storage. A charge level of the primary battery component is detected. It is determined that the charge level of the primary battery component is less than a minimum threshold. The mobile device is switched from a primary mode to a secondary mode, based on the charge level being less than the minimum threshold. A secondary battery component powers the secondary storage in the secondary mode, and the critical data is accessible on the secondary storage in the secondary mode.

Methods and devices are provided for quick charging. In the method, after a mobile terminal recognizes a type of a power adapter, the mobile terminal transmits indication information to the power adapter. The indication information is configured to indicate that the mobile terminal has recognized the type of the power adapter and instruct the power adapter to activate a quick charging process. The power adapter then negotiates with the mobile terminal via the quick charging process to determine charging parameters, and charges a battery of the mobile terminal in a multi-stage constant current mode.

Methods and devices are provided for quick charging. In the method, after a mobile terminal recognizes a type of a power adapter, the mobile terminal transmits indication information to the power adapter. The indication information is configured to indicate that the mobile terminal has recognized the type of the power adapter and instruct the power adapter to activate a quick charging process. The power adapter then negotiates with the mobile terminal via the quick charging process to determine charging parameters, and charges a battery of the mobile terminal in a multi-stage constant current mode.

Systems and methods for automated broadband distribution point unit powering are provided. In one embodiment, an upstream service disconnect unit comprises: a processor; a relay control; and a switching relay coupled to a upstream service delivery unit, a first end of an electrical conductor span, and a access network distribution point unit that is coupled to an optical fiber network, wherein a second end of the electrical conductor span is coupled to a customer premises equipment DSL modem; wherein the upstream service disconnect unit is configured to energize the processor, the relay control, and the switching relay and to operate the switching relay to couple the electrical conductor span with the access network distribution point unit by tapping power of a trigger signal drawn from the electrical conductor span.

Systems and methods for automated broadband distribution point unit powering are provided. In one embodiment, an upstream service disconnect unit comprises: a processor; a relay control; and a switching relay coupled to a upstream service delivery unit, a first end of an electrical conductor span, and a access network distribution point unit that is coupled to an optical fiber network, wherein a second end of the electrical conductor span is coupled to a customer premises equipment DSL modem; wherein the upstream service disconnect unit is configured to energize the processor, the relay control, and the switching relay and to operate the switching relay to couple the electrical conductor span with the access network distribution point unit by tapping power of a trigger signal drawn from the electrical conductor span.