An approach is provided that receives radio frequency (RF) requests at a vehicle. The approach determines that the received request is a possible unauthorized intrusion. The approach then responsively transmits a confirmation request to a mobile device associated with an authorized user of the vehicle and safeguards the vehicle until a positive confirmation is received at the vehicle from the mobile device.

A vehicle safety system. The vehicle safety system includes a control unit, a mobile device receiver, and a speed sensor. The control unit is operably connected to a vehicle with which the system is to be used. During use of the system, the mobile device receiver registers a mobile device coupled thereto, and the control unit deactivates the vehicle if the mobile device is removed from the mobile device receiver when the vehicle is in motion and may send an alert to an authority if a particular speed is exceeded.

A vehicle control system (VCS) includes external communication interfaces, such as a Bluetooth interface, for communicating with a user communication and control device, such as a smart phone or a tablet. The user is enabled to operate certain features of the vehicle, such as the remote start, power locks/trunk, climate control, and security features, through the smart phone. The VCS may also communicate with a remote server via the user's smartphone, for example, providing telematics data and receiving service reminders for display to the user on the smartphone, the VCS, or a display built into the vehicle. The VCS may be custom installed in the vehicle using the user's or the installer's smartphone, without a physical connection from the VCS to the smartphone.

A vehicle control system (VCS) includes external communication interfaces, such as a Bluetooth? interface, for communicating with a user communication and control device, such as a smart phone or a tablet. The user is enabled to operate certain features of the vehicle, such as the remote start, power locks/trunk, climate control, and security features, through the smart phone. The VCS may also communicate with a remote server via the user's smartphone, for example, providing telematics data and receiving service reminders for display to the user on the smartphone, the VCS, or a display built into the vehicle. The VCS may be custom installed in the vehicle using the user's or the installer's smartphone, without a physical connection from the VCS to the smartphone.

An apparatus includes a vehicle control system (VCS) coupled to a computer of a vehicle via a CAN bus and configured to present selectively appearance of a presence in the vehicle of a smartkey, e.g., by energizing and de-energizing an actual smartkey of the vehicle. The VCS includes a VCS and a Bluetooth? VCS transceiver. The VCS stores VCS software. The apparatus also includes a smartphone with a Bluetooth? transceiver, and storing an app. The mobile device is paired with the VCS to communicate with the VCS via a Bluetooth? link. The app configures the smartphone to receive menu selections from a user, to generate communications that identify smartkey-enabled features of the VCS that correspond to the selections, and to send to the VCS the communications through the link. The VCS software configures the VCS to receive the communications and cause the vehicle to perform actions corresponding to the communications.

A system for securing of vehicles includes at least one server; at least one vehicle having a vehicle processing device and a vehicle communication device designed to communicate with the server via at least one mobile radio network, wherein the vehicle processing device is designed to transmit data to the server; and at least one mobile terminal device, in particular a smartphone. The server has at least one allocation table which assigns at least one terminal device to the at least one vehicle. The server is designed to: (a) determine, by using the transmitted data, whether the vehicle is being moved without authorization; (b) determine, in the event of unauthorized movement of the vehicle, the associated terminal device using the allocation table; and/or (c) send a warning message to the associated terminal device in the event of unauthorized movement.

A vehicular headlamp comprising: a front lens body extending in a predetermined direction; a plurality of optical systems disposed along the predetermined direction behind the front lens body; and a control means, wherein the plurality of optical systems each includes: a rear lens unit disposed behind the front lens body; and a light source which is disposed behind the rear lens unit and emits light which is irradiated forward permeating the rear lens unit and the front lens body in that order to form a light distribution pattern for a headlamp, and the control means individually controls lighting states of the light sources in each of the plurality of optical systems.

A sound output apparatus and a sound output control method including a sound output controller placed in a vehicle having a door lockable and unlockable based on the result of communicated with mobile terminals are disclosed. The vehicle mounted with the sound output controller and a locking and unlocking system including the vehicle are also disclosed. The sound output controller outputs a sound that is different between when the door is unlocked by a specified mobile terminal and when the door is unlocked by other means.

A vehicle locking and unlocking control system, comprising: a lock trigger that is provided outside a vehicle and outputs an output signal when operated by a person; a vehicle side transmitter is configured to transmit a transmission request signal according to reception of the output signal output by the lock trigger; a mobile wireless terminal is configured to transmit a response signal according to reception of the transmission request signal transmitted by the vehicle side transmitter; a vehicle side receiver configured to receive the response signal transmitted by the mobile wireless terminal; a locking controller configured to determine whether or not the response signal received by the vehicle side receiver is suitable for a unique identification signal of the vehicle and output a lock signal on the basis of a result of the determination and the reception of the output signal output from the lock trigger; a door lock mechanism configured to lock a door according to the lock signal output by the locking controller; a first determiner configured to determine whether a driving source for driving the vehicle is in an on state or a power supply of the vehicle is in an on state; a second determiner configured to determine whether or not the mobile wireless terminal is outside the vehicle; a door state detector configured to detect an open state of the door; an alarm output unit configured to output an alarm; and an alarm controller configured to cause the alarm output unit to output an alarm after it is determined by the first determiner that the driving source of the vehicle is in an on state or the power supply of the vehicle is in an on state, the output signal output from the lock trigger has been received, and a predetermined period of time has elapsed from a time when it is determined by the second determiner that the mobile wireless terminal is outside the vehicle, and cause the alarm output unit not to output the alarm when it is detected by the door state detector that the door is in the open state before the predetermined period of time elapses.

Disclosed is a system for detecting an operating state of a vehicle engine. The system comprises: an input coupled to a power line of a vehicle; means to filter out relatively high frequency transient noise components of a signal received from the power line; a first detector for receiving the filtered signal and detecting when transient noise associated with the power line rises above a first threshold and generating a first detection signal in response thereto; a second detector for receiving the filtered signal and detecting when the transient noise falls below a second threshold, which is lower than the first threshold, and generating a second detection signal in response thereto; and means for generating a first output signal in response to the first detection signal and a second output signal in response to the second detection signal.