A system for connected vehicle control may include a communicator configured to connect with a user terminal though wireless communication, and generate authentication information by combining user terminal information and vehicle information, a head unit having a password for operation and configured to generate a visible code by converting the authentication information, a body controller configured to control the vehicle according to a remote control signal sent according to a remote control function of a user application installed in the user terminal, and a controller configured to connect the communicator, the head unit, and the user application through the wireless communication, authenticate, and register.

A receiver circuit is provided. The receiver circuit includes an antenna configured to receive a radio frequency (RF) signal; a filter configured to filter the RF signal received by the antenna; and a passive mixer circuit configured to adjust a center frequency of the filtered RF signal to a predetermined frequency. The passive mixer circuit includes: a transformer which includes a first coil and a second coil that is separate from the first coil; a first passive mixer which is directly connected to a first end of the second coil; and a second passive mixer which is directly connected to a second end of the second coil and is separate from the first passive mixer.

A smart locker system includes an enclosure unit and a cassette unit. The smart locker is extendable by adding additional enclosure units and the cassette units. The cassette unit includes storage bins and a control bin. The cassette unit contains different size of storage bins and a control bin. The smart locker system further includes a touch screen and authentication devices. The smart locker system can arrange the storage bins and the control bins to maintain the height of the smart locker system.

The present application provides a data management method, apparatus, device, system and storage medium for a smart lock. The smart lock includes: respective databases corresponding to N unlock modes, N is an integer greater than 1, and the method includes: receiving a registration command transmitted by a terminal device; acquiring first unlock information of a current unlock mode according to the registration command; and storing the first unlock information of the current unlock mode into a database corresponding to the current unlock mode. Therefore, unlock efficiency of the smart lock is improved.

A power over Ethernet (PoE)-based redundant power management method manages a redundant power supply electrically connectable to plural network devices through plural twisted pairs respectively, so as to transmit first electricity and digital information to each network device. The redundant power supply receives a power demand message from, and is informed of the electric power needed by, each network device electrically connected to the redundant power supply. In response to determining the second electricity each such network device has been receiving is interrupted, the redundant power supply outputs to each such network device the corresponding first electricity equal to the electric power needed by the network device through a corresponding Ethernet port. In response to receiving a power-off request message from any such network device, the redundant power supply stops outputting to that network device the corresponding first electricity.

An IO-link device (20) configured as slave for transmitting/receiving signal data with a master module (19), the IO-link device comprising: a sensor or actuator (11) configured to produce output measurement signals; a first microcontroller (21) operatively coupled to the sensor or actuator and configured to receive the measurement signals and generate data based on the measurement signals, and a transceiving module (22) which comprises a physical layer transceiver (24) configured to receive/transmit signal data from/to the master module (19), and a second microcontroller (23) operatively coupled and in bi-directional communication with the transceiver, wherein the transceiver (24) is configured to receive signal data associated with a request from the master module (19) and transmit signal data associated with the request to the second microcontroller (23) and the second microcontroller (23) is configured to receive the signal data from the transceiver and to execute a device IO-Link protocol stack, the second microcontroller being operatively coupled and in bi-directional communication with the first microcontroller (21) for the transmission of signal data associated with the request to the first microcontroller and to receive data based on measurement signals from the first controller.

The present embodiments relate generally to data communications, and more particularly to systems including high-speed serializer-deserializer circuits having TCOILs. One or more embodiments are directed to a four-terminal TCOIL structure that consumes the same amount of area on a chip as a traditional three-terminal structure, while providing more bandwidth and less reflection and group delay variation.

A system is provided for allowing temporary access to a desired area. The temporary access may be for the purposes of making a delivery. The system comprises a trainable transceiver configured to transmit an activation signal to a remote device; a mobile communications device in selective communication with the trainable transceiver; and an accessory selectively securable to mobile communications device and capable of transmitting information to trainable transceiver.

A first transmission line and a second transmission line that are connected in series to each other are disposed at different positions in a thickness direction of a substrate. A third transmission line is disposed between the first transmission line and the second transmission line in the thickness direction of the substrate. The third transmission line includes a first end portion connected to one end portion of the first transmission line, and a second end portion that is AC-grounded. The first transmission line and the second transmission line are electromagnetically coupled to the third transmission line.

There is provided a power conditioning circuit including positive and negative power input nodes. An inductor includes a first terminal connected to a positive power input node and a second terminal connected to a positive power output node, the inductor allowing the voltage at the positive power output node to be modulated by data that is sent through a communication interface. A first node is present between the second terminal of the inductor and the positive power output node, and a clamping circuit is connected at the first node to a second node. The clamping circuit is configured to clamp a voltage increase across the inductor to less than a maximum increase. The second node is configured to be continuously held at a voltage higher than the voltage of the first terminal of the inductor.