A key system for an automobile according to the present disclosure includes an on-vehicle device configured to transmit and receive a radio signal to and from an electronic key, and a resin panel through which the on-vehicle device is fixed to and held by a body of the automobile. The on-vehicle device includes a transmitter configured to transmit a search signal to the electronic key, a receiver configured to receive a response signal transmitted from the electronic key in response to the search signal, a control unit configured to control the transmission of the search signal, and a resin case. The smart key system for the automobile according to the present disclosure removes electrostatic charging generated by the search signal transmitted from the transmitter in either or both of the resin case and the resin panel.

A vehicle remote control key system and a method of processing a signal in the system are provided. The system includes a remote control key that is configured to send out a radio frequency (RF) signal that includes an identification (ID) and operation information to remotely control a target vehicle based on a remote control key operation. In addition, a controller is configured to determine whether the ID of the received RF signal is available and perform the remote control when the ID is available and the controller retransmits the RF signal to a vehicle in the vicinity of the target vehicle when the ID is unavailable and increases a count bit, which stores the number or times of retransmission in a frame, by one when retransmitting the RF signal.

Systems and methods for verifying remote device proximity in RFID systems are described. To reduce the risk of relay attacks, a terminal may determine a distance of a remote device from the terminal. The terminal may send a computational challenge to the remote device and determine whether a latency of the response is within a maximum acceptable latency, indicating that the remote device is within a maximum acceptable distance. The maximum acceptable latency may be dynamically determined based on context information, such as a time of day, that may be correlated with a likelihood of attempted unauthorized accesses. The terminal may determine whether to perform an action associated with the remote device based on whether the response was received within the maximum acceptable latency.

A vehicle door access control method comprises using a smart mobile device to obtain management authority of an external door access device. Then, the smart mobile device is used to authorize the unlocking authority to a vehicle host, such that the external door access device permits use of the smart mobile device or the vehicle to proceed with unlocking or opening operation.

Embodiments of a device for wireless communication are disclosed. In some embodiments, the device includes: a transceiver configured to receive a message from a second device and at least one processor. The processor is communicatively coupled to the transceiver and is configured to: generate a response message includes a SYNC portion, a start frame delimiter (SFD) portion, and a cipher portion. The SYNC portion includes a sequence of symbols forming a preamble. The cipher portion includes a ciphered sequence of pseudo-randomized pulses. The transceiver is further configured to transmit the response message.

Embodiments of a device for wireless communication are disclosed. In some embodiments, the device includes: a transceiver configured to receive a message from a second device and at least one processor. The processor is communicatively coupled to the transceiver and is configured to: generate a response message includes a SYNC portion, a start frame delimiter (SFD) portion, and a cipher portion. The SYNC portion includes a sequence of symbols forming a preamble. The cipher portion includes a ciphered sequence of pseudo-randomized pulses. The transceiver is further configured to transmit the response message.

Embodiments of a device for wireless communication are disclosed. In some embodiments, the device includes: a transceiver configured to receive a message from a second device and at least one processor. The processor is communicatively coupled to the transceiver and is configured to: generate a response message includes a SYNC portion, a start frame delimiter (SFD) portion, and a cipher portion. The SYNC portion includes a sequence of symbols forming a preamble. The cipher portion includes a ciphered sequence of pseudo-randomized pulses. The transceiver is further configured to transmit the response message.

Systems, apparatuses, and methods for implementing efficient power optimization in a computing system are disclosed. A system management unit configured to track computing activity of a computing device while processing each frame of a plurality of frames. The computing activity is tracked at least for a given period of time comprising a plurality of time slices. The system management unit further correlates a time slice associated with a given frame with a time slice associated with at least one previously processed frame from the plurality of frames, based at least in part on the tracked computing activity. The system management unit predicts a clock frequency to render the given frame, based at least in part on the correlation and renders the given frame using the predicted clock frequency.

Systems and methods for verifying remote device proximity in RFID systems are described. To reduce the risk of relay attacks, a terminal may determine a distance of a remote device from the terminal. The terminal may send a computational challenge to the remote device and determine whether a latency of the response is within a maximum acceptable latency, indicating that the remote device is within a maximum acceptable distance. The maximum acceptable latency may be dynamically determined based on context information, such as a time of day, that may be correlated with a likelihood of attempted unauthorized accesses. The terminal may determine whether to perform an action associated with the remote device based on whether the response was received within the maximum acceptable latency.