Embodiments are disclosed for an example driver assistance system for a vehicle. The example driver assistance system includes a sensor module communicatively coupled to one or more sensors, a processor, and a storage device storing instructions executable by the processor to, responsive to detecting an entry condition, disengage control of the vehicle by a driver of the vehicle, and engage autopilot of the vehicle upon detecting a leading vehicle in front of the vehicle. The instructions are further executable to follow the leading vehicle at a threshold separation until detecting an exit condition.

The disclosure relates to a method for automatic longitudinal control of a motor vehicle and to a corresponding assistance system and a motor vehicle equipped therewith or, alternatively, configured accordingly. In the method, within the scope of user-side setting of a gap for the longitudinal control, a display position for displaying a relevant gap marker by means of a head-up display is determined proceeding from the position of a vehicle in front. In response to a user input for setting a changed new gap, the previous gap marker and the new gap marker are then initially displayed simultaneously by means of the head-up display at the corresponding display positions. When the longitudinal control has achieved the new gap, the head-up display is actuated to only display the new gap marker and not the previous gap marker anymore.

The invention relates to an adaptive cruise control (ACC) system for a host motor vehicle having regenerative braking means (122) and non-regenerative braking means. The system is operable to control a powertrain and the braking means of the host vehicle to maintain the vehicle at a target distance (d_target) behind the followed vehicle, the target distance being substantially equal to a second distance that is greater than a first distance (d_driver); and employ substantially only the regenerative braking means and not the non-regenerative braking means to slow the host vehicle when the host vehicle is greater than the first distance (d_driver) behind the followed vehicle and the ACC system determines that braking is required to maintain the vehicle at the target distance.

When employing an adaptive cruise-with-braking (ACB) system to control host vehicle braking reaction distance, a plurality of trigger conditions (e.g., environmental parameters) are monitored. If one or more of the monitored parameters exceeds a predefined threshold, a trigger event is detected, and at least one of a braking reaction distance (BRD) and a following distance limit shape (FDLS) are adjusted. The BRD and FDLS adjustments may be predefined according to the type and/or magnitude of the trigger event. Trigger events may be weighted or prioritized such that higher priority trigger event types correspond to larger BRD reductions, etc. Monitored trigger conditions may include adverse weather, dangerous road terrain or topography, high traffic density, erratic forward vehicle behavior, and the like.

Embodiments are disclosed for an example driver assistance system for a vehicle. The example driver assistance system includes a sensor module communicatively coupled to one or more sensors, a processor, and a storage device storing instructions executable by the processor to, responsive to detecting an entry condition, disengage control of the vehicle by a driver of the vehicle, and engage autopilot of the vehicle upon detecting a leading vehicle in front of the vehicle. The instructions are further executable to follow the leading vehicle at a threshold separation until detecting an exit condition.