An acceleration slip regulation method includes determining a current control phase of a vehicle in an acceleration slip regulation state, determining a current road surface adhesion coefficient of the vehicle, determining, based on the current control phase and the current road surface adhesion coefficient, maximum torque allowed by a road surface, obtaining demand torque received by a drive motor of the vehicle and a wheel slip rate of the vehicle, and outputting adaptive feedforward torque for acceleration slip regulation based on the maximum torque allowed by the road surface, the demand torque, and the wheel slip rate, where the adaptive feedforward torque is used to perform the acceleration slip regulation on the vehicle.

An acceleration slip regulation method includes determining a current control phase of a vehicle in an acceleration slip regulation state, determining a current road surface adhesion coefficient of the vehicle, determining, based on the current control phase and the current road surface adhesion coefficient, maximum torque allowed by a road surface, obtaining demand torque received by a drive motor of the vehicle and a wheel slip rate of the vehicle, and outputting adaptive feedforward torque for acceleration slip regulation based on the maximum torque allowed by the road surface, the demand torque, and the wheel slip rate, where the adaptive feedforward torque is used to perform the acceleration slip regulation on the vehicle.

A vehicle control apparatus that provides control over a brake device or a power plant device of a host vehicle includes: an information acquisition part configured to acquire information on state of the brake device and the power plant device and information on front wheel steering angle; a determination part configured to determine whether or not an abnormality has occurred in a turnability improvement control; a deceleration force computation part configured to compute a required deceleration force; and a coordinated control part configured to perform a coordinated control in which a distribution ratio between a brake deceleration force of the brake device and a power plant deceleration force of the power plant device is adjusted. When an abnormality has occurred in the turnability improvement control, a sum of the brake deceleration force and the power plant deceleration force is degenerated according to a prescribed time rate of change.

A vehicle control apparatus that provides control over a brake device or a power plant device of a host vehicle includes: an information acquisition part configured to acquire information on state of the brake device and the power plant device and information on front wheel steering angle; a determination part configured to determine whether or not an abnormality has occurred in a turnability improvement control; a deceleration force computation part configured to compute a required deceleration force; and a coordinated control part configured to perform a coordinated control in which a distribution ratio between a brake deceleration force of the brake device and a power plant deceleration force of the power plant device is adjusted. When an abnormality has occurred in the turnability improvement control, a sum of the brake deceleration force and the power plant deceleration force is degenerated according to a prescribed time rate of change.

A control device for a vehicle equipped with a steering system including a steering wheel (13), a rack (12) for steering the wheels (4) of the vehicle, and a redundant arrangement for transmitting a displacement of the steering wheel to the rack, wherein upon detecting a failure in the redundant arrangement, the control device sets an upper limit speed to a first value in a first stage, and changes the upper limit speed from the first value to a second value smaller than the first value in a progressive manner in a second stage that follows the first stage.

An environment detection device for a vehicle is includes a sensor unit for determining environment information of a surrounding area of the vehicle itself, with a temperature measurement unit, configured to measure at least one state temperature of the sensor unit, and with a controller, configured to trigger at least one action for reducing the state temperature if a prescribed temperature warning value is exceeded.

An environment detection device for a vehicle is includes a sensor unit for determining environment information of a surrounding area of the vehicle itself, with a temperature measurement unit, configured to measure at least one state temperature of the sensor unit, and with a controller, configured to trigger at least one action for reducing the state temperature if a prescribed temperature warning value is exceeded.

Described herein are systems, methods, and non-transitory computer-readable media for isolating commercial components from a harsh vehicle operating environment to increase the longevity of such components and to decrease their failure rate. Also described herein are systems, methods, and non-transitory computer-readable media for monitoring the operational health status of vehicle components for failure, and upon detecting failure of a component, initiating a processing task reassignment and fault recovery process. In this manner, processing load handled by the component prior to failure can be offloaded to one or more other vehicle components while a fault recovery process is initiated for the component. When the failed component is operational again, the vehicle may revert back to the task assignment in place prior to the component failure, may continue with the current task assignment, or may transition to another different task reassignment.

Described herein are systems, methods, and non-transitory computer-readable media for isolating commercial components from a harsh vehicle operating environment to increase the longevity of such components and to decrease their failure rate. Also described herein are systems, methods, and non-transitory computer-readable media for monitoring the operational health status of vehicle components for failure, and upon detecting failure of a component, initiating a processing task reassignment and fault recovery process. In this manner, processing load handled by the component prior to failure can be offloaded to one or more other vehicle components while a fault recovery process is initiated for the component. When the failed component is operational again, the vehicle may revert back to the task assignment in place prior to the component failure, may continue with the current task assignment, or may transition to another different task reassignment.

Techniques for determining a degraded state associated with a sensor are discussed herein. For example, a sensor associated with vehicle may captured data of an environment. A portion of the data may represent a portion of the vehicle. Data associated with a region of interest can be determined based on a calibration associated with the sensor. For example, in the context of image data, image coordinates may be used to determine a region of interest, while in the context of lidar data, a beam and/or azimuth can be used to determine a region of interest. A data metric can be determined for data in the region of interest, and an action can be determined based on the data metric. For example, the action can include cleaning a sensor, scheduling maintenance, reducing a confidence associated with the data, or slowing or stopping the vehicle.