A vehicle control system includes: an outside-of-vehicle operation device configured to cause a vehicle to travel operated by an operator from outside of the vehicle, inside of a compartment of the vehicle being isolated from the outside of the vehicle by a vehicle body; an assist instruction device configured to cause the operator to select a travel mode in which the vehicle is allowed to travel by an operation of the outside-of-vehicle operation device; a parking brake operation detector configured to detect an operation of a parking brake; and a warning device configured to issue warning in a compartment to stimulate sense of hearing or sense of sight at the time the travel mode is selected and the operation of the parking brake is detected.

A method for checking a capacity of at least one supply line for an electrically operated assembly that is coupled electrically via the at least one supply line to an electrical system of an at least partially automated mobile platform. The method includes: ensuring a non-critical operating state of the mobile platform; determining an off-load terminal voltage at an input connection of the assembly, with zero-current supply line; applying a defined current to the supply line of the electrically operated assembly; determining an on-load terminal voltage at the input connection of the assembly, in doing so, the defined voltage being applied to the supply line of the electrically operated assembly; determining a differential voltage between the off-load terminal voltage and the on-load terminal voltage; comparing the differential voltage to a differential-voltage limit value to determine whether the capacity of the electric supply line is sufficient to operate the assembly.

An image processing device for a vehicle includes: an acquisition unit acquiring a captured image of a periphery of a vehicle, which is captured by an imaging unit provided in the vehicle; a bird's eye view image generating unit generating a bird's eye view image in which the captured image is projected to a 3D virtual projection plane provided at a side opposite to the vehicle with reference to a ground and separated from the ground with distance from the vehicle; a guide line generating unit generating a guide line indicating a predicted course of the vehicle; a conversion unit converting the guide line into a virtual guide line indicating the predicted course on the virtual projection plane; and a superimposing unit superimposing the virtual guide line on the bird's eye view image.

A controller for a motor vehicle brake system includes a first functional assembly for controlling a service brake and a second functional assembly for controlling a parking brake. The first and the second functional assemblies can be supplied by separate voltage supplies. The controller is configured in such a way that, in the event of a fault in or affecting the first or the second functional assembly, the respective other functional assembly remains ready for use for at least a defined period of time, and the motor vehicle can be braked by means of the ready-for-use functional assembly within the defined period of time in order to engage a transmission lock of the vehicle and/or in order to hold the vehicle at a standstill using the parking brake.

A vehicle, a vehicle speed control system, and a method of controlling vehicle speed are provided. The vehicle may include a powertrain and a controller. The controller may be programmed to reduce a powertrain output based on a braking comfort parameter such that a speed becomes less than a threshold speed associated with the parking maneuver prior to completion of the parking maneuver.

A drive source controller is configured to control a drive torque of a drive source that drives a vehicle. The drive source controller is configured to prohibit acceptance of drive source required torque from a cruise controller when automatic braking control is activated during cruise control, or not output the drive source required torque to the drive source controller when the automatic braking control is activated during the cruise control.

A method for operating a vehicle in at least one parking process situation involves allocating at least one predetermined vehicle-specific or parking process situation-specific function to the at least one predetermined parking process situation of the vehicle. Whether the vehicle is in the at least one predetermined parking process situation is determined and the predetermined vehicle-specific or parking process situation-specific function allocated to the at least one predetermined parking process situation is presented to a vehicle user for activation or automatically activated when the vehicle is in the at least one predetermined parking process situation.

A parking control apparatus, for a vehicle including a plurality of wheels, that includes: a processor that is configured to: individually control the wheels to be braked, released, or driven, and, based on control of the wheels, turn the vehicle about an axis that is perpendicular to ground is disclosed.

In a method for activating and deactivating a control unit which can be used to control an electrically activatable assembly, the control unit is switched between a waking state, a sleep state and a deactivated state, wherein in the sleep state, the control device is disabled but can be transferred into the waking state by means of a sensor signal.

The present disclosure relates to a vehicle having a park-by-brake module that can control an electronic parking brake coupled to the rear wheels of a vehicle. The park-by-brake module is coupled to an antilock brake module by a controller area network architecture. In one example, a first controller area network and a second controller area network are used to couple the park-by-brake module to the antilock brake module. The controller area network architecture allows the park-by-brake module to receive commands from various control modules. Based on the received commands, the park-by-brake module activates or deactivates the electronic parking brake.