A method and system are provided for adapting a vehicle control strategy of an on-road vehicle following a reoccurring fixed route to a predetermined destination, which fixed route extends through at least one geographical zone associated with at least one environmental restriction. When it is determined that the vehicle is approaching the geographical zone, historical data collected from previous passages of one or several vehicles through the zone is accessed, and the vehicle control strategy inside the geographical zone is adapted based on the historical data and the environmental restriction.

A system for operating an autonomous vehicle includes a passenger-detector and a controller-circuit. The passenger-detector is operable to determine a passenger-count of passengers present in a host-vehicle. The controller-circuit is in communication with the passenger-detector and vehicle-controls of the host-vehicle. The controller-circuit is configured to operate the host-vehicle in an autonomous-mode and in accordance with a parameter. The parameter is set to an empty-value when passenger-count is equal to zero, and the parameter is set to an occupied-value different from the empty-value when the passenger count is greater than zero.

An autonomous vehicle, including a vehicle body, a wheel supported by the vehicle body, a steering mechanism configured to change a travel direction, a driving/braking force generating device configured to generate a driving force or a braking force to drive or decelerate the autonomous vehicle, a plurality of seats each configured to be sat on by a passenger, and an autonomous driving controller configured to control the steering mechanism and the driving/braking force generating device to autonomously drive the autonomous vehicle without any driver's manipulation. The autonomous driving controller is configured to determine whether or not to control the driving/braking force generating device to change the autonomous vehicle from a stopped state to a run state, based on (1) at least one of a number of passengers, a maximum capacity, or a scheduled number of passengers, and (2) at least one of a number of sitting passengers or a number of ready-state-expressing passengers.

The technology relates to autonomous vehicles having articulating sections such as the trailer of a tractor-trailer. Aspects include approaches for tracking the pose of the trailer, including its orientation relative to the tractor unit. Sensor data is analyzed from one or more onboard sensors to identify and track the pose. The pose information is usable by on-board perception and/or planning systems when driving the vehicle in an autonomous mode. By way of example, on-board sensors such as Lidar sensors are used to detect the real-time pose of the trailer based on Lidar point cloud data. The orientation of the trailer is estimated based on the point cloud data, and the pose is determined according to the orientation and other information about the trailer. Aspects also include determining which side of the trailer the sensor data is coming from. A camera may also detect trailer marking information to supplement the analysis.

A method for detecting pedestrians in a vicinity of a vehicle is disclosed. The method includes: receiving image data acquired using one or more cameras, the image data depicting at least a portion of the vehicle's surroundings and at least one human subject; determining image coordinates corresponding to one or more parts of a body of the at least one human subject that are detected in the image data; obtaining vehicle environment information for the vehicle, the vehicle environment information identifying a plurality of regions that are defined in an area surrounding the vehicle; determining that the at least one human subject is present within a first one of the plurality of regions based on the image coordinates corresponding to the one or more detected body parts; and generating a notification indicating the detected presence of the at least one human subject in the first region.

An autonomous dining vehicle characterized as a mobile restaurant, bar or a limousine comprising a lower floor, an upper floor connected by multiple steps, a kitchen area for cooking meals all made on the lower floor, a consumption area including tables and seating on the lower and upper floors, at least one restroom, door and a ramp for access. A driver may provide manual driving or a driver operating from a control center systematically provides autonomous driving to autonomously control steering and propulsion said wheel-set.

A method, a device, a storage medium and a vehicle for vehicle rollover prevention warning, wherein the method for vehicle rollover prevention warning includes: collecting vehicle body rollover state parameters; calculating a lateral-load transfer rate of the vehicle according to the collected vehicle body rollover state parameters and a preset load transfer rate threshold model comprising the centrifugal force rollover moment of the sprung mass; and determining whether the vehicle has the risk of rollover or not according to the calculated lateral-load transfer rate and the preset rollover threshold. According to the technical solution provided by the invention, the load transfer rate threshold model based on the centrifugal force rollover moment of the sprung mass can simulate the actual rollover state of a vehicle more truly, with a more accurate state indication effect and a high warning accuracy.

The present invention relates to a method for decelerating a vehicle comprising an electrical machine being arranged to provide a controllable torque to at least one drive wheel, said vehicle including driver controllable means for actively requesting a torque for propelling the vehicle. The method includes, when a driver request for a propelling torque is reduced at least to a first extent: applying a first brake torque by means of said electrical machine, by means of said first brake torque, decelerate said vehicle to a stationary state, and by means of said electrical machine, when said vehicle has been decelerated to said stationary state, continue applying a torque by means of said electrical machine to keep said vehicle in said stationary state.

A system for monitoring occupancy of a seat arranged in a transportation vehicle is disclosed. The system includes at least one detection device arranged in the vehicle, within the seat or near the seat, and at least one centralized occupancy management system located outside of the vehicle and at least one occupancy management system located outside of the vehicle. An occupancy displaying unit is arranged on the seat or next to the seat for providing visual information about seat occupancy. The passenger's mobile communication device is used by the system for locating the passenger inside the transportation vehicle, by means of dedicated device detection units arranged in the transportation vehicle. The centralized occupancy management system and the occupancy management system are informed in real-time about the seat's occupancy.

An automatic driving vehicle is running in an automatic driving mode effected by a driving control device. An operator is able to instruct via a SLOW DOWN button on a touch panel that the automatic driving vehicle is to be decelerated or stopped. Should any anomaly occur to the SLOW DOWN button, a message or the like is displayed on a touch panel to encourage operation of an emergency stop switch. When the operator operates the emergency stop switch, emergency stop control is executed.