A driving system for a motor vehicle includes a first driving function for automated driving with automated longitudinal and transverse guidance and a second driving function for automated driving with at least automated longitudinal guidance, or with at least automated transverse guidance. The second driving function has a lower degree of automation than the first driving function. The first driving function is available in a tolerance range. Starting from a driving state with an active second driving function and a value of the driving parameter outside the tolerance range, the driving system changes, when the second driving function is active, the value of the driving parameter in the direction of the tolerance range via automated longitudinal guidance or automated transverse guidance. The driving system then determines that the driving parameter satisfies a criterion with respect to the tolerance range.

A traveling-speed control device restricts a traveling speed such that the traveling speed falls within an allowable range from a spot reference speed for a current spot, the spot reference speed being acquired from a spot reference speed storage area in which spot reference speeds at respective spots are stored, the spot reference speeds being set based on respective pieces of traveling speed data at the respective spots. Hereby, a vehicle can travel at a more appropriate traveling speed at each spot regardless of whether the each spot is on a road on map data or not.

Terrain characteristics of an off-road area are determined based on a map. The terrain characteristics include a terrain type, a terrain grade, and a presence or an absence of an obstacle. Vehicle characteristics are determined including a ground clearance and a breakover angle. Based on a user level, vehicle parameters for the off-road area are determined based on the terrain characteristics, the vehicle characteristics, and the user input. The vehicle parameters include a speed and a transmission gear. The vehicle parameters for the off-road area are output.

A vehicle control system includes a recognizer that recognizes a surrounding environment of a vehicle, and a driving controller that performs speed control and steering control of the vehicle based on a recognition result of the recognizer. When moving the vehicle to a parking area after detecting that an occupant gets off the vehicle at a stop position, the driving controller adjusts a start timing for starting the vehicle based on the number of vehicles stopped at the stop position recognized by the recognizer.

Systems and methods for predictive adaptive cruise control of a plurality of vehicles traveling in succession. A system engages in a vehicle-to-vehicle communication session with one or more vehicles of the plurality of vehicles. During the communication session, terrain information is obtained and first speed trajectory information is determined for an upcoming segment of road. Second speed trajectory information is received from a first adjacent vehicle of the plurality of vehicles. Third speed trajectory information is generated based on the second speed trajectory information received and the terrain information. The operation of the vehicle is controlled during the upcoming segment according to the third speed trajectory information.

A cloud application may suggest speeds to vehicles based on weather and road conditions in order to improve vehicle safety. Status information associated with a vehicle may be received from one or more computing devices associated with the vehicle. The status information may comprise a location and a speed of the vehicle. A weather condition and a road condition associated with an upcoming location of the vehicle may be obtained. The upcoming location may be determined based at least in part on the received location of the vehicle. A suggested speed at the upcoming location may be determined for the vehicle based at least in part on the weather condition and the road condition. It may be determined that the received speed of the vehicle is greater than the suggested speed. The suggested speed may be sent to the one or more computing devices associated with the vehicle.

In one embodiment, a speed planning system receives speed limit information for an autonomous driving vehicle (ADV), where the speed limit information includes a change in road speed limit for a current road of the ADV. The system determines a tapered speed limit corresponding to the current road based on the speed limit information, where the tapered speed limit correspond to a gradual speed reduction from a first road speed limit to a second road speed limit. The system determines a cost function based on the tapered speed limit and the first and second road speed limits. The system generates a number of trajectory candidates based on the cost function. The system selects a trajectory based on the trajectory candidates to control the ADV using the selected trajectory.

A vehicle speed control method, an apparatus, a device and a storage medium applied to a vehicle. The method includes: receiving (S210) a speed limit command sent by a speed control device, where the speed limit command includes a speed limit, and the speed limit command is generated by the speed control device when it is determined a position of the vehicle is in an area where an accident occurrence rate is greater than or equal to a preset threshold; reducing (S220) a travelling speed of the vehicle to less than the speed limit in response to the speed limit command. According to the vehicle speed control method, vehicle speed can be controlled according to actual safety situation on a road, thereby improving safety of vehicle travelling.

A travel control device includes: a risk level calculation unit configured to acquire a speed in a traveling direction of a vehicle, a speed of the vehicle in a horizontal direction perpendicular to the traveling direction, and an azimuth angular velocity of the vehicle and calculate a rollover risk level based on a lateral load transfer ratio (LTR) of the vehicle; a deceleration calculation unit configured to calculate deceleration indicating an extent to which to lower the speed in the traveling direction when an absolute value of the rollover risk level exceeds a threshold value; and a control unit configured to control a driving system of the vehicle using a value obtained by lowering a target speed of the vehicle on the basis of the deceleration as a new target speed.

Systems and methods are provided herein for controlling the speed on each wheel of a vehicle, possibly operating a vehicle in a speed control mode. In response to receiving input to engage speed control mode and receiving an accelerator pedal input, the system determines a target wheel speed based on the accelerator pedal input, monitors wheel speed of each of a plurality of wheels and determines, for each monitored wheel, a difference based on the monitored wheel speed and the target wheel speed. A torque is provided to each of the plurality of wheels based on the respective difference to achieve the target wheel speed.