A vehicle control system includes an in-vehicle device, a mobile terminal, and one or more processors. The in-vehicle device is mounted on a vehicle. The in-vehicle device controls a lock mechanism that locks and unlocks a door of the vehicle. The in-vehicle device causes the lock mechanism to unlock the door in response to a predetermined condition being satisfied. The mobile terminal communicates with the in-vehicle device. The one or more processors determine whether the mobile terminal is present inside a vehicle compartment. The one or more processors detect whether the mobile terminal is used. The one or more processors control the vehicle control system not to satisfy the predetermined condition in response to determination that the mobile terminal is present inside the vehicle compartment.

A vehicle theft-prevention apparatus can include at least one computing device couple to a plurality of sensors and a wireless transceiver. The plurality of sensors can be configured to sense measurements proximate to a vehicle. The at least one computing device can be configured to read a plurality of first measurements of a first sensor of the plurality of sensors. Based on the plurality of first measurements from the first sensor, the at least one computing device can determine that a key fob moved outside of a range of the first sensor. In response to the key fob moving outside of the range of the first sensor, the at least one computing device can transition to an armed state. The at least one computing device can read a plurality of second measurements from a subset of the plurality of sensors. Based on the plurality of second measurements, the at least one computing device can determine that a person has entered the vehicle.

A vehicle control device includes: a power-supply control unit that sets a power supply to an off state when either a first power-off condition in which a user performs a power-off operation or a second power-off condition in which a first predetermined time elapses from the time when the user U gets off the vehicle with the power supply in an on state is satisfied; and a power-on-condition setting unit that: sets a power-on condition to a first power-on condition, when the power supply is set to the off state because the first power off condition is satisfied; and sets the power-on condition to a second power-on condition that is different from the first power-on condition, when the power supply is set to the off state because the second power off condition is satisfied.

A control method of a smart welcome system of a vehicle includes emitting a low-frequency signal of a first power to search for a smart key in a first search area, emitting a high-frequency signal by the smart key, determining that the smart key is within the first search area, carrying out authentication for the smart key, transmitting a wake-up signal to an AVNT smart connection device, and emitting a low-frequency signal of a second power to search for the smart key in a second search area, executing a booting program, transmitting a high-frequency signal by the authenticated smart key, determining that the authenticated smart key is within the second search area, unfolding a side mirror and outputting a welcome sound output signal to a welcome speaker, and outputting a welcome sound simultaneously with unfolding the side mirror.

A vehicular exterior component, such as a handle assembly for a closure of a vehicle, includes a force-based sensor disposed behind an outer wall and responsive to forces applied thereto. The vehicular exterior component may include a force-sensitive printed circuit board (PCB) configured to detect touch forces at either of an inner surface or an outer surface of the outer wall of the vehicular exterior component and to distinguish between those different touch forces in order to provide corresponding unlock or lock signals. A short-range RADAR antenna may be disposed within the vehicular exterior component and adjacent to the outer wall. A passive keyless entry (PKE) antenna may also disposed within the vehicular exterior component and adjacent to the outer wall.

A vehicle includes a first sensor that senses a state of the vehicle and a second sensor that senses outside of the vehicle. A computing device is configured to receive signals from the sensors and to control rotating and turning of the wheels. While the vehicle is parked, the computing device determines according to a signal received from the sensors, that a condition is satisfied. The condition may be associated with a particular wheel. Based on determining that the condition is satisfied, and while the vehicle remains parked, the computing device initiates automatically rotating or turning the particular wheel associated with the condition.

A vehicle system may include a plurality of wireless transmitters carried by a vehicle and configured to transmit wireless signals, at least one indicator carried by the vehicle, and a portable device moveable relative to the vehicle and configured to receive the wireless signals from the plurality of wireless transmitters. The system may further include a controller carried by the vehicle and configured to wirelessly communicate with the portable device, and determine a predicted zone the portable device is located in adjacent to the vehicle based upon the received wireless signals, with the predicted zone being one of a plurality of different zones adjacent the vehicle having respective vehicle functions associated therewith. The controller may be further configured to cause the at least one indicator to provide an indication that the portable device has entered the predicted zone, and enable the respective vehicle function associated with the predicted zone.

An example operation includes one or more of establishing a security level based on an environment of a transport, determining a minimal radio frequency signal strength needed for a device to communicate with the transport based on the security level of the transport, and performing a command, by the transport, based on the communication when the minimal radio frequency signal strength is achieved.

A method and system for detecting if a relay is present in a PEPS system for a vehicle is provided which includes (a) transmitting LF signals from antennas associated with a vehicle to a key fob using a 3D LF receiver to measure the LF signal level on the x, y and z-axes; (b) selecting two or more parallel antennas associated with the vehicle that are orthogonal to the antenna at the PEPS triggering location; (c) normalizing the x, y and z vectors that are measured by the key fob for the selected two or more parallel antennas associated with the vehicle; and (d) determining if the normalized x, y and z vectors for the selected two or more parallel antennas associated with the vehicle are within a predefined range.

A vehicle, including: a first antenna module located inside the vehicle and including a communication antenna and a communication module; a second antenna module located outside the vehicle and including a communication antenna and a communication module; and a controller configured to control the first antenna module and the second antenna module to wirelessly communicate with each other, identify a distance from the vehicle to a digital key through a communication between the second antenna module and the digital key to control the vehicle, and identify whether the digital key is inside the vehicle by scanning the inside of the vehicle by the first antenna module to control the vehicle.