An electronic device includes a control unit that allows at least a first external power source to be connected thereto and is activated upon receipt of a predetermined power, and a power source connected to the control unit. In an activated state, the control unit performs enumeration processing between the control unit and the first external power source. The power source has charging unit capable of being charged by a charge current supplied from the first external power source, and output unit that outputs the predetermined power from the charging unit to the control unit in response to a connection between the control unit and the first external power source. The charging unit sets the charge current to a current value according to whether the enumeration processing is completed.

Removable modules configured to charge a device with a power connector configured to operate at specified power parameters. The removable module removably and electrically couples to a base module mounted to a panel and in electrical communication with a power supply. The removable module includes an electronics system and a power receptacle. The electronics system converts a supply current from the removable module to an output current matching the specified power parameters of the power connector. The power receptacle is complementarily configured with the power connector to electrically couple with the power connector. In some examples, the removable module is part of a set of removable modules to charge different devices with different power connectors and/or different specified power parameters.

A device having a function of simultaneously charging and backing up data is provided. The device includes a transmission interface, a power supply circuit, a storage circuit, and a main control circuit. The transmission interface is connected to an electronic device. The power supply circuit is configured to supply power to the electronic device to charge the electronic device. The storage circuit is configured to access data of the electronic device, or to provide data stored in the storage circuit to the electronic device. The main control circuit is connected to the transmission interface, the power supply circuit and the storage circuit. The main control circuit is configured to control the power supply circuit to supply the power to the electronic device and the storage circuit to back up the data simultaneously.

The present utility model belongs to that technical field of data transmission and connection, in particular to a device for improving a charging transmission power for external equipment based on the USB port of a computer. The device of the present utility model specifically comprises a computer connecting terminal, an external equipment connecting terminal and a control circuit arranged between the computer connecting terminal and the external equipment connecting terminal for controlling the charging transmission power; wherein the control circuit is provided with a first main control chip, and an LX end of the first main control chip is connected with a fifth inductor; the other end of the fifth inductor is provided with a 102nd capacitor and an 18th capacitor; the other ends of the 102nd capacitor and the 18th capacitor are respectively grounded. On the one hand, the device can achieve the normal charging function of the USB port of a computer during data transmission between computer and device; on the other hand, the device can maintain stable exaggerated charging current and power supply during data transmission, thus solving the problems of battery capacity dropping and charge failure of the portable rechargeable virtual-reality device during use.

A charging circuit includes at least two charging chips for charging a battery of an electronic device. Each of the at least two charging chips is configured to operate in an independent charging mode. Each charging chip includes a first voltage sampling end and a second voltage sampling end for collecting voltage information of the battery, and each charging chip is configured for independent charging according to the collected voltage information. The first voltage sampling end and the second voltage sampling end are respectively connected to two poles of the battery.

The present disclosure provides a fast charging driver. The fast charging driver is configured to charge a battery of an electronic device. The fast charging driver includes a fast charging circuit and a charging controller. The fast charging circuit includes a first depletion-type GaN transistor, a first enhancement-type field effect transistor, a second depletion-type GaN transistor and a second enhancement-type field effect transistor. The charging controller is configured to control the fast charging circuit to operate in a constant current mode or a constant voltage mode according to a battery level of the battery. By utilizing the first depletion-type GaN transistor and the second depletion-type GaN transistor with a characteristic of a relatively low switching loss, the power consumption during charging the battery by the fast charging driver is decreased to improve the charge speed.

An electrical outlet device and system for providing light and power during the night or during a power failure. The device and system includes rechargeable energy storage devices that can be utilized to provide power to the outlet(s) and the light sources. The device and system can have two sections, a main and a removable section both having their own energy storage devices and light sources. The removeable section may connected with a computing device that can interface with a wireless module to transmit/receive data packets wirelessly.

A multiplexing circuit, an interface circuit system, and a mobile terminal, to resolve a problem that a charging current significantly decreases when a headset is used during charging of the mobile terminal. In a multiplexing circuit, a first switch circuit transmits a right-channel audio signal on a right-channel transmission end to a first external transmission end; a second switch circuit transmits a left-channel audio signal on a left-channel transmission end to a second external transmission end; when a second on voltage is received, but a first on voltage is not received, an isolation circuit transmits the second on voltage to a third switch circuit; and when the first on voltage and the second on voltage are received, the isolation circuit pulls down the third switch circuit, and isolates a ground end from a second on voltage end.

A ladder having a first front rail. The ladder has a second front rail in parallel and spaced relation with the first front rail. The ladder as a first rung attached to and positioned between the first front rail and the second front rail. The ladder as a receptacle attached to the ladder which is adapted to receive a battery. The receptacle having electrical contacts for the battery and an electrical outlet. The ladder has a wiring harness attached to the ladder and electrically connected to the electrical outlet to receive electricity from the battery. A method for providing electricity from a ladder. A method for making a ladder.

A charger extension device has a housing having a top side, a left side, a bottom side, a right side, a rear side, a front side, and an interior, an USB port on the front side of the housing, a port on the rear side of the housing, and a quick charging circuit in the interior between the USB port on the front side of the housing and the port on the rear side of the housing.