Aspects of the disclosure provide systems and methods for providing suggested locations for pick up and destination locations. Pick up locations may include locations where an autonomous vehicle can pick up a passenger, while destination locations may include locations where the vehicle can wait for an additional passenger, stop and wait for a passenger to perform some task and return to the vehicle, or for the vehicle to drop off a passenger. As such, a request for a vehicle may be received from a client computing device. The request may identify a first location. A set of one or more suggested locations may be selected by comparing the predetermined locations to the first location. The set may be provided to the client computing device.

Systems and methods for a vehicle to use a fallback control system orthogonal to a primary control system are provided. A method includes collecting, by a fallback control system of a vehicle, sensor data generated by one or more sensors of the vehicle; determining, by the fallback control system using a first process different from a second process of a primary control system of the vehicle, an alternative action for the vehicle based on the sensor data; and sending, by the fallback control system based on the alternative action, an instruction for modifying an action associated with the primary control system upon a faulty condition associated with the primary control system.

Embodiments of the invention provide a vehicle comprising actuator operable to provide motive power to the vehicle, the vehicle being operable automatically to switch off and subsequently to restart the actuator thereby to reduce an amount of time the actuator is on, wherein the vehicle may be placed in an eco-stop condition by a driver-operated brake in which the vehicle is held stationary and the actuator is off, the vehicle being operable automatically to perform an eco-start operation in which the actuator is restarted when the driver releases the brake, wherein when an eco-start is performed the vehicle is arranged automatically to be held stationary by the brake whilst the actuator is restarted, if the actuator fails to restart the vehicle being further arranged automatically to assume a failed start condition in which the vehicle continues to be held stationary.

In a travel control apparatus for a vehicle, a travel environment information acquisition unit acquires travel environment information on a travel environment of the vehicle. A travel information detector detects travel information on the vehicle in order to execute automatic driving control based on such information pieces. A lateral force generator generates lateral force to be applied to the vehicle during the automatic driving control. A torsion bar is interposed on a torque transmission path of a steering system. A steering wheel angle detector detects a steering wheel angle. A lateral force detector detects the lateral force acting on the vehicle. An intervening steering operation determination unit determines that a driver has performed an intervening steering operation when a characteristic of the detected steering wheel angle and lateral force differs from a reference characteristic that varies univocally when the steering wheel is in a no load condition.

A control system for hybrid vehicle for extending a possible travelling distance of the vehicle in the event of clutch failure is provided. The control system is configured to select a first drive mode in which the vehicle is powered by an engine in case an estimated torque transmitting capacity of the clutch in trouble is larger than a first threshold value, and to select a second drive mode in which the vehicle is powered by a motor in case the estimated torque transmitting capacity of the clutch in trouble is smaller than the first threshold value. The control system is further configured to reduce an engine torque to be smaller than the estimated torque transmitting capacity of the clutch in case the first drive mode is selected.

A method for controlling a steer-by-wire system, comprising receiving vehicle data and a steering request from a vehicle, determining whether a steering road wheel actuator of the vehicle has failed using the vehicle data, in response to determining that the steering road wheel actuator of the vehicle has failed, determining a target wheel slip of the vehicle based on the steering request, maintaining the target wheel slip of the vehicle while the vehicle is in motion; and adjusting a wheel speed of at least one wheel of the vehicle based on a feedback signal, wherein the feedback signal is indicative of a road wheel angle while the vehicle is in motion.

This application relates to a vehicle control method and system, a vehicle, and a storage medium. The vehicle control method includes: when a braking system fails, activating a backup braking system, the backup braking system decelerating a vehicle by controlling a regenerative motor; when a steering system fails, implementing transverse control over the vehicle by controlling the braking system; and when a parking system fails, implementing parking by controlling a motor and the braking system to work alternately. According to this method, safety control over the vehicle can be implemented when the original braking system, steering system, or parking system fails.

A method for operating a vehicle in an automated driving operation involves a main control device determining a driving instruction and providing it to an auxiliary control device. The driving instruction includes information about a course of a path on which the vehicle should be guided into a stopping position, which is determined by a series of path points having a spacing value assigned to each path point. The spacing value corresponds to a spacing of the path point from left or right lane markings. Spacing values are transmitted to the auxiliary control device as digital data having a limited representable value range of the spacing values. The spacing values are reduced by scaling before the transmission to the auxiliary control device, and are calculated back in the auxiliary control device after the transmission if a lane width is greater than the representable value range of the spacing values.

A vehicle includes a battery and a computing system that analyzes a first calculation related to driving control of the vehicle and a second calculation related to energy management of the vehicle, obtains battery state information related to the battery, and manages processing of the first calculation and the second calculation based on the battery state information.

A vehicle system includes a processing device programmed to monitor an operating state of a vehicle and the operation of at least one subsystem module. Depending on the operating state of the vehicle, the processing device can detect a subsystem module failure. If a failure is detected, the processing device can perform a remedial action. The remedial action taken may be based on the type of failure detected.