A vehicle assist server performs a vehicle assist for an object vehicle using a previously generated assist content, based on object vehicle data including a traveling state of the object vehicle and position information about the object vehicle on a map. The vehicle assist server includes a prevalence degree estimation unit, a prevalence degree determination unit, and a registration unit.

Systems and methods for controlling a vehicle are provided. The systems and methods include a sensor system and a processor configured to execute program instructions, to cause the at least one processor to: receive yaw rate values, lateral acceleration values and longitudinal velocity values for the vehicle from the sensor system, determine side slip angle parameter values based on the yaw rate values, lateral acceleration values and longitudinal velocity values, determine phase portrait angles based on the side slip angle parameter values and the yaw rate values, wherein the phase portrait angles each represent an angle between yaw rate and side slip angle for the vehicle in a phase portrait of yaw rate and side slip angle, detect or predict vehicle instability based at least on the phase portrait angles, and when vehicle instability is detected or predicted, control motion of the vehicle to at least partly correct the vehicle instability.

Systems and methods for controlling a vehicle are provided. The systems and methods include a sensor system and a processor configured to execute program instructions, to cause the at least one processor to: receive yaw rate values, lateral acceleration values and longitudinal velocity values for the vehicle from the sensor system, determine side slip angle parameter values based on the yaw rate values, lateral acceleration values and longitudinal velocity values, determine phase portrait angles based on the side slip angle parameter values and the yaw rate values, wherein the phase portrait angles each represent an angle between yaw rate and side slip angle for the vehicle in a phase portrait of yaw rate and side slip angle, detect or predict vehicle instability based at least on the phase portrait angles, and when vehicle instability is detected or predicted, control motion of the vehicle to at least partly correct the vehicle instability.

A display system comprises a camera for capturing traveling video of a vehicle. a sensor for detecting traveling state information of the vehicle, a display device, and one or more processors. The one or more processors execute calculating a steady circular turning trajectory of the vehicle based on the traveling state information, estimating a slip angle of the vehicle based on the traveling state information, rotating the steady circular turning trajectory in accordance with the slip angle to calculate a predicted trajectory, and displaying the traveling video and the predicted trajectory on the display device in a superimposed manner.

A display system comprises a camera for capturing traveling video of a vehicle. a sensor for detecting traveling state information of the vehicle, a display device, and one or more processors. The one or more processors execute calculating a steady circular turning trajectory of the vehicle based on the traveling state information, estimating a slip angle of the vehicle based on the traveling state information, rotating the steady circular turning trajectory in accordance with the slip angle to calculate a predicted trajectory, and displaying the traveling video and the predicted trajectory on the display device in a superimposed manner.

A vehicle control apparatus according to the present invention outputs a signal regarding a target braking/driving force for guiding a vehicle in a target traveling direction to a braking/driving controller. The signal regarding the target braking/driving force is acquired based on information regarding a running route of the vehicle and a physical amount regarding a motion state of the vehicle. The vehicle control apparatus outputs a signal regarding a steering correction torque for correcting a steering torque according to a behavior of the vehicle to a steering force controller. The signal regarding the steering correction torque is acquired based on a vehicle-body slip angle of the vehicle and the target braking/driving force.

A traveling control system includes a first acquisition unit, a second acquisition unit, a path plan setter and a controller. The first a acquisition unit communicates with a cloud environment including an edge environment to acquire cloud information including traveling information of other vehicles from at least the edge environment. The second acquisition unit recognizes a traveling environment of an own vehicle and acquires own vehicle traveling information including the recognized traveling environment and a vehicle control state of the own vehicle. The path plan setter sets a path plan in automatic driving control to cause the own vehicle to travel automatically. The determines a need for changing the path plan and the automatic driving control based on the cloud information and controls traveling behavior of the own vehicle according to the need for a change based on the cloud information and the own vehicle traveling information.

A traveling control system includes a first acquisition unit, a second acquisition unit, a path plan setter and a controller. The first a acquisition unit communicates with a cloud environment including an edge environment to acquire cloud information including traveling information of other vehicles from at least the edge environment. The second acquisition unit recognizes a traveling environment of an own vehicle and acquires own vehicle traveling information including the recognized traveling environment and a vehicle control state of the own vehicle. The path plan setter sets a path plan in automatic driving control to cause the own vehicle to travel automatically. The determines a need for changing the path plan and the automatic driving control based on the cloud information and controls traveling behavior of the own vehicle according to the need for a change based on the cloud information and the own vehicle traveling information.

This vehicle relative-position calculation device includes: a vehicle state information acquisition unit for acquiring state information of an own vehicle during traveling; a surrounding object information acquisition unit for acquiring information of a surrounding object around the own vehicle; a relative-position information conversion input unit to which relative-position information determined from the state information of the own vehicle and the information of the surrounding object, is inputted, and which converts the inputted relative-position information to relative-position information for which a specific position on the own vehicle is set as an origin; a position information storage unit which stores the relative-position information converted and a vehicle-fixed coordinate conversion unit to which the state information of the own vehicle acquired, is inputted, and which converts the relative-position information stored in the position information storage unit to present-time relative-position information, and outputs the present-time relative-position information to the position information storage unit.

This vehicle relative-position calculation device includes: a vehicle state information acquisition unit for acquiring state information of an own vehicle during traveling; a surrounding object information acquisition unit for acquiring information of a surrounding object around the own vehicle; a relative-position information conversion input unit to which relative-position information determined from the state information of the own vehicle and the information of the surrounding object, is inputted, and which converts the inputted relative-position information to relative-position information for which a specific position on the own vehicle is set as an origin; a position information storage unit which stores the relative-position information converted and a vehicle-fixed coordinate conversion unit to which the state information of the own vehicle acquired, is inputted, and which converts the relative-position information stored in the position information storage unit to present-time relative-position information, and outputs the present-time relative-position information to the position information storage unit.