The present invention relates to a device and a method for transmitting or receiving data in a wireless power transmission system. The present specification discloses a wireless power reception device comprising: a power pickup unit configured to receive, from a wireless power transmission device, wireless power generated on the basis of magnetic coupling in a power transmission phase; and a communication/control unit configured to receive, from the wireless power transmission device, information on a first buffer size indicating the size of a first buffer for receiving a data transmission stream. As the buffer size for exchanging the data transmission stream between the wireless power transmission device and reception device becomes clear, wireless power transmission and communication can proceed smoothly.

A system automatically detecting that an authorized game device or object with a rechargeable battery is close to or in contact with a wireless charging pod for the gaming device or object, automatically initiating and managing charging operations for authorized game device, and automatically deactivating the charging operations when the rechargeable batteries are fully charged, or when the authorized game device is moved out of wireless charging range.

The present invention relates to a device and a method for transmitting or receiving data in a wireless power transmission system. The present specification discloses a wireless power reception device comprising: a power pickup unit configured to receive, from a wireless power transmission device, wireless power generated on the basis of magnetic coupling in a power transmission phase; and a communication/control unit configured to receive, from the wireless power transmission device, information on a first buffer size indicating the size of a first buffer for receiving a data transmission stream. As the buffer size for exchanging the data transmission stream between the wireless power transmission device and reception device becomes clear, wireless power transmission and communication can proceed smoothly.

A battery system includes a system controller connected to a controller area network (CAN) bus, and stations respectively connected to nodes of the CAN bus, wherein, a first station of the stations is configured to detect that a first battery pack has been coupled thereto, and is configured to transmit a first detection signal to the system controller, wherein the system controller is configured to provide a first wake-up signal for waking up the first battery pack to the first station in response to the first detection signal, wherein the first station is configured to wake up a first battery controller of the first battery pack in response to the first wake-up signal, and wherein the system controller is configured to be woken up and to transmit a command for allocating a first identifier (ID) corresponding to the first station to the first battery controller having a default ID via the CAN bus.

Disclosed is a method for identifying an RFID card as a passive or an active RFID card comprising sending a first RFID command, while keeping an RFID field on; receiving, from the RFID card a corresponding first answering signal; populating a first list with each corresponding first answering signal from the RFID card; sending a second RFID command, wherein the RFID field is paused for a predefined pausing period after sending the second RFID command; receiving, from at least zero active RFID cards, a corresponding second answering signal; populating a second list with each corresponding second answering signal from the at least zero active RFID cards; comparing the entries of the first list with the entries of the second list; identifying each of the at least zero passive RFID cards by having the corresponding first answering signal in the first list but not in the second list.

A data line and a charging device are provided. The data line includes a Type-A port, a first port, a cable, and a circuit identification module. VBUS pins, D+ pins, D− pins, and GND pins in the Type-A port and the first port are connected in one-to-one correspondence. The circuit identification module includes a pull-up resistor, a switch circuit, and a detection circuit. A first terminal of the switch circuit is connected to the CC pin of the first port, a second terminal is connected to the VBUS pin through the pull-up resistor, a third terminal is connected to the CC pin of the Type-A port, an input terminal of the detection circuit is connected to the CC pin of the Type-A port, and an output terminal is connected to a control terminal of the switch circuit.

A system includes a battery having a battery controller and a container including a plurality of receptacles, each receptacle being shaped to receive the battery. The system also includes a charging device including a plurality of charging bays, wherein each charging bay is shaped to receive a respective receptacle of the plurality of receptacles. Each charging bay includes a first antenna configured to provide charging power to the battery, a second antenna configured to communicate with the battery controller, and a charger controller. The charger controller is configured to detect a presence of the battery within a receptacle associated with a charging bay, establish communication with the battery using the second antenna while the first antenna is deactivated, pair the battery to the charging device, activate the first antenna after the battery is paired, and provide charging power to the battery using the first antenna.

Systems and components are provided for charging an Information Handling System (IHS). Systems include an AC adapter configured to report attributes of the adapter. The adapter includes a DC cord that supports a data channel. The DC plug includes a circuit for operating an indicator light based on an control signal. The system includes a power port controller that receives the reported adapter attributes, determines a charging state of the IHS; generates the control signal based on the determined charging state; and transmits the control signal to the indictor light circuit via the data channel. The indicator control signal may be used to operate indicator lights on both ends of a reversible DC cord. The indicator control signal may specify a color or brightness of the indicator and may indicate a charging state of the IHS.

Controller of power storage pack performs communication for authentication with controller of an electric moving body according to the pattern of a current flowing through a power line in a state where power storage pack is mounted to electric moving body. Controller of power storage pack measures contact resistance between power storage pack and the electric moving body based on voltage of the power line on power storage pack side, voltage of the power line on the electric moving body side received from controller of the electric moving body, and current when communication for authentication is performed according to the pattern of a current flowing through the power line.

The disclosure provides a detection signal for detecting a power receiving device in wireless charging, wherein the detection signal is configured to wake up the power receiving device in a wireless charging field, and cause the power receiving device to generates a feedback signal based on a modulation wave of about 2kHz; a duration time of the detection signal is greater than 1 millisecond and less than 65 milliseconds; and the detection signal is configured to identify the modulation wave. The disclosure further provides a wireless charging method for a wireless charging device using the detection signal, and a wireless charging device using the detection signal.