An actuator for an electric parking brake, EPB, is described. The actuator comprises a motor configured to actuate an actuating member of the EPB, as well as a reception interface configured to receive an enablement code. An enablement code is assigned to the EPB actuator which individualizes the EPB actuator against other EPB actuators. The actuator further comprises an evaluation unit configured to verify the received enablement code on the basis of the enablement code allocated to the EPB actuator and to enable a control of the motor in case of a positively verified enablement code. There is further provided a control device for the EPB actuator, an electric parking brake and a vehicle having the EPB actuator and corresponding operating methods.

Cargo anti-theft systems, apparatus, and related methods. Anti-theft controllers of embodiments are configured to sense the openings of cargo switches and to electronically operate locks responsive thereto. Moreover, the switches are mechanically coupled to the access points in manners such that the access points cannot be opened without opening the switches. Some controllers are configured to output signals indicative of openings of the switches while some are configured to unlock the locks only in pre-selected geo-zones. The pre-selected voltages, moreover, can differ from 12 VDC and can be user-selected. Furthermore, controllers can be configured to sense (modifiable) PINs associated with openings of the cargo switches. The controllers can include a coupler which securely couples it to the vehicle. It can also be configured to sense a position of the lock. Such controllers, furthermore, can be configured to lock the lock responsive to the lock position and/or can comprise a battery.

Cargo anti-theft systems, apparatus, and related methods. Anti-theft controllers of embodiments are configured to sense the openings of cargo switches and to electronically operate locks responsive thereto. Moreover, the switches are mechanically coupled to the access points in manners such that the access points cannot be opened without opening the switches. Some controllers are configured to output signals indicative of openings of the switches while some are configured to unlock the locks only in pre-selected geo-zones. The pre-selected voltages, moreover, can differ from 12 VDC and can be user-selected. Furthermore, controllers can be configured to sense (modifiable) PINs associated with openings of the cargo switches. The controllers can include a coupler which securely couples it to the vehicle. It can also be configured to sense a position of the lock. Such controllers, furthermore, can be configured to lock the lock responsive to the lock position and/or can comprise a battery.

A system for managing door operation of a vehicle includes a door system and a doorjamb system configured for the door to close against. The door system includes a door having a handle mechanism, an indicator mechanism coupled to the handle mechanism and actuated by motion of the handle mechanism, and a latch feature configured to be engaged for latching the door closed. The doorjamb system includes a sensor configured to generate a sensor signal indicative of a state of the indicator mechanism, and a latching mechanism configured to secure and release the latch feature of the door. Control circuitry of the vehicle is coupled to the sensor and latching mechanism, and is configured to receive the sensor signal, and control the latching mechanism based on the sensor signal. The control circuitry determines state information for the vehicle and determines whether to secure or release the latch mechanism.

A system for managing door operation of a vehicle includes a door system and a doorjamb system configured for the door to close against. The door system includes a door having a handle mechanism, an indicator mechanism coupled to the handle mechanism and actuated by motion of the handle mechanism, and a latch feature configured to be engaged for latching the door closed. The doorjamb system includes a sensor configured to generate a sensor signal indicative of a state of the indicator mechanism, and a latching mechanism configured to secure and release the latch feature of the door. Control circuitry of the vehicle is coupled to the sensor and latching mechanism, and is configured to receive the sensor signal, and control the latching mechanism based on the sensor signal. The control circuitry determines state information for the vehicle and determines whether to secure or release the latch mechanism.

A method for controlling a vehicle feature includes registering a GPS-based vehicle speed based on information from a vehicle GPS-receiver, and changing an operating setting of, or activating, the vehicle feature when the GPS-based vehicle speed is more than zero km/h, specifically more than 3 km/h, and more specifically more than 6 km/h, while the vehicle is parked.

A method for controlling a vehicle feature includes registering a GPS-based vehicle speed based on information from a vehicle GPS-receiver, and changing an operating setting of, or activating, the vehicle feature when the GPS-based vehicle speed is more than zero km/h, specifically more than 3 km/h, and more specifically more than 6 km/h, while the vehicle is parked.

A tire theft alarming system includes a vehicular device mounted to a vehicle and a mobile device carried by a user of the vehicle. When a main power supply of the vehicle is in an OFF state, the vehicular device transmits a radio wave including a first alarm based on having a variation in air pressure or acceleration of a tire, which is mounted to the vehicle, detected by a sensor transmitter for detecting and transmitting the air pressure of the tire or the acceleration applied to the tire. The mobile device carries out a warning notification to a user based on having reception of a radio wave including a first alarm transmitted by the vehicular device.

A tire theft alarming system includes a vehicular device mounted to a vehicle and a mobile device carried by a user of the vehicle. When a main power supply of the vehicle is in an OFF state, the vehicular device transmits a radio wave including a first alarm based on having a variation in air pressure or acceleration of a tire, which is mounted to the vehicle, detected by a sensor transmitter for detecting and transmitting the air pressure of the tire or the acceleration applied to the tire. The mobile device carries out a warning notification to a user based on having reception of a radio wave including a first alarm transmitted by the vehicular device.

An electronic door locking system of a motor vehicle is disclosed, comprising at least one receiver for the transmission signals of an electronic key, at least one control device for mechanically locking and unlocking at least one motor vehicle door, at least one contact element, accessible from outside the motor vehicle, for connecting an external voltage source, wherein the at least one control device for mechanically locking and unlocking at least one motor vehicle door and/or at least one additional control device has an emergency power supply algorithm, wherein the electronic door locking system is designed to detect an emergency power supply mode and to activate the emergency power supply algorithm, wherein the emergency power supply algorithm is designed to deactivate at least one function of a normal mode and/or, in the case of a function, to access previously defined data of deactivated components or to ignore said data.