A driver assistance system in a motor vehicle includes a map-based detection system for detecting upcoming events which lead to a change in the maximum permissible speed, and a functional unit which, when a relevant upcoming event is detected by the map-based detection system, at a defined time before the upcoming event is reached, initiates an output of a request indication to permit an automatic adjustment of the current maximum permissible speed to a new maximum permitted speed. When a manually triggered authorization confirmation or detected rejection is identified the functional unit, initiates a withdrawal of the request indication. The functional unit is configured to prompt a withdrawal of the output of the request indication after passing the relevant upcoming event when there is no detected authorization confirmation or no detected rejection.

Systems and methods for adaptive cruise control based on user defined parameters are disclosed. An example disclosed vehicle includes a GPS receiver configured to provide a location of the vehicle, an adaptive cruise control; and a cruise control adjuster. In the example cruise control adjuster is configured to generate an action when a cruise control event is defined for the location. In the disclosed example the cruise control event is based on past changes to the adaptive cruise control at the location. The example cruise control adjuster is also configured to apply the action to the adaptive cruise control to change how the adaptive cruise control controls the vehicle.

Provided is a control method of an automatic driving vehicle switchable between manual driving in which the vehicle is made to travel depending on an operation of an occupant and automatic driving in which driving characteristics in automatic travel are set and the vehicle is made to automatically travel based on the driving characteristics. Manual driving characteristics in the manual driving by the occupant are learned and, when switching from the manual driving to the automatic driving is performed, the automatic driving is performed with the manual driving characteristics maintained for a preset manual characteristic maintaining time. As a result, uneasiness of the occupant can be suppressed.

A speed control system (12) for a vehicle (100), the speed control system (12) being configured to: automatically cause application of positive and negative torque, as required, to one or more wheels of a vehicle (100) to cause a vehicle to travel in accordance with a target speed value, the target speed value being stored in a memory of the control system (12); and detect a crest of a slope ahead of the vehicle (100); wherein the speed control system (12) is configured automatically to attempt to adjust a speed of the vehicle (100) to cause the vehicle (100) to travel at a predetermined crest speed value when a crest of a slope is detected ahead of the vehicle (100), the predetermined crest speed value being determined in dependence at least in part on terrain gradient information respect of terrain prior to the crest.

In one embodiment, speeds of an autonomous driving vehicle (ADV) are captured in response to a series of speed control commands issued at different points in time represented by a series of command cycles. For each of the command cycles, a first speed-changing rate is calculated based on a corresponding speed of the ADV and a second speed-changing rate is calculated based on the corresponding speed and a corresponding speed control command using a predetermined algorithm or function. A unit gain of speed control is determined using a cost function based on the first speed-changing rates and the second speed-changing rates, such that the cost representing a difference between the first speed-changing rates and the second speed-changing rates. The unit gain is then utilized to generate subsequent speed control commands for operating the ADV.

When an accept operation for permitting a speed limit to be set as a target speed has been detected, a driving support ECU gradually increases the current target speed toward the current speed limit. The target speed is displayed in a gradual-change display screen on a display apparatus. A driver performs a correcting operation at the time at which the driver recognizes that the displayed target speed exceeds the speed limit. The driving support ECU corrects the target speed based on the correcting operation.

An adaptive cruise control system and method for controlling a speed of a vehicle includes determine a distance between a controlled vehicle a target vehicle with a distance sensor. An input sensor senses an input from a driver of the controlled vehicle in relation to the desired distance between the controlled vehicle and the target vehicle. An adaptive cruise control module receives a data set of a plurality of data points regarding the operation of the controlled vehicle. An artificial neural network is configured to receive the data set in response to the input from the driver being sensed and calculate a change in the desired distance in response to a change in at least one of the data points. A requested distance between vehicles is then changed based on at least one of the input from the driver and the calculated change in the desired distance by the artificial neural network.

A travel assist device includes: a creation unit configured to create a traveling profile based on a total traveling distance; and an output unit configured to output an operation amount according to a target state amount, which is a target value of a state amount indicated by the traveling profile, to at least one of a driving device and a braking device. In a state in which a vehicle travels by the driving of at least one of the above devices based on the operation amount, the creation unit re-creates a traveling profile so that the acceleration of the vehicle does not exceed a predetermined limit value if the difference between an actual value of the state amount and the target state amount is equal to or larger than a judgment difference.

In accordance with an aspect of the present disclosure, cruise control of an automotive vehicle in a fuel economy cruise control mode controls vehicle speed to be within a fuel economy speed band about a cruise control set speed so that instantaneous fuel economy is at least equal to average fuel economy.

A method is provided to control the acceleration of a motor vehicle from a current speed, wherein the motor vehicle includes an accelerator pedal system able to generate on the accelerator pedal an added reaction force when the depression of the accelerator pedal reaches a given depression level. The method includes the steps of: a) measuring the current vehicle speed; b) determining a target speed of the motor vehicle in function at least of the current vehicle speed or determining from the current vehicle speed a maximum acceleration rate; c) determining at least one threshold depression level of the accelerator pedal that corresponds to the stabilization of the vehicle speed at the target speed or that corresponds to maximum acceleration rate; d) generating an added reaction force on the accelerator pedal if the depression of the accelerator pedal reaches or is about to reach the threshold depression level; wherein at least steps a), b), and c) are automatically repeated as vehicle speed increases.