Technologies and techniques for the restrained movement of a vehicle with a drive unit for accelerating the vehicle, and a braking unit for braking the vehicle. A restraining drive torque is generated by the drive unit, and a braking torque is generated by the braking unit to compensate for the restraining drive torque and thereby to generate a restraining torque in the vehicle, and braking the vehicle by reducing the drive torque. A device and a computer program product may be configured to implement the restraining movement processes and a storage may be configured with a processor to execute the computer program product.

Technologies and techniques for the restrained movement of a vehicle with a drive unit for accelerating the vehicle, and a braking unit for braking the vehicle. A restraining drive torque is generated by the drive unit, and a braking torque is generated by the braking unit to compensate for the restraining drive torque and thereby to generate a restraining torque in the vehicle, and braking the vehicle by reducing the drive torque. A device and a computer program product may be configured to implement the restraining movement processes and a storage may be configured with a processor to execute the computer program product.

A computer includes a processor and a memory storing instructions executable by the processor to receive data indicating a lane change by a first vehicle that is towing a second vehicle, the data including data indicating a direction that first wheels of the first vehicle are turning while the first vehicle is performing the lane change; and during the lane change, instruct a steering system of the second vehicle to turn second wheels of the second vehicle in a same direction as the first wheels.

A computer includes a processor and a memory storing instructions executable by the processor to receive data indicating a lane change by a first vehicle that is towing a second vehicle, the data including data indicating a direction that first wheels of the first vehicle are turning while the first vehicle is performing the lane change; and during the lane change, instruct a steering system of the second vehicle to turn second wheels of the second vehicle in a same direction as the first wheels.

Described herein are various technologies pertaining to selecting an autonomous vehicle for a trip of a passenger based on a passenger cargo reservation request and real time load data from a fleet of autonomous vehicles. The passenger cargo reservation request specifies a request to store passenger cargo in a cargo storage area of an autonomous vehicle during a ride of a passenger in the autonomous vehicle. Further, an autonomous vehicle from the fleet of autonomous vehicles can be selected for the trip of the passenger based on the passenger cargo reservation request and the real time load data for the autonomous vehicles in the fleet of autonomous vehicles.

Described herein are various technologies pertaining to selecting an autonomous vehicle for a trip of a passenger based on a passenger cargo reservation request and real time load data from a fleet of autonomous vehicles. The passenger cargo reservation request specifies a request to store passenger cargo in a cargo storage area of an autonomous vehicle during a ride of a passenger in the autonomous vehicle. Further, an autonomous vehicle from the fleet of autonomous vehicles can be selected for the trip of the passenger based on the passenger cargo reservation request and the real time load data for the autonomous vehicles in the fleet of autonomous vehicles.

An agricultural sprayer includes a computing system configured to receive a first input associated with a target application rate at which agricultural fluid is to be dispensed onto the field. Moreover, the computing system is configured to receive a second input associated with a turn being made or to be made by the sprayer. Additionally, the computing system is configured to determine a maximum ground speed for the turn at which a selected nozzle dispenses the agricultural fluid onto the field at the target application rate based on the received first and second inputs. Furthermore, when the turn is being made, the computing system is configured to control an operation of the sprayer such that the ground speed of the sprayer is at or below the determined maximum ground speed.

An agricultural sprayer includes a computing system configured to receive a first input associated with a target application rate at which agricultural fluid is to be dispensed onto the field. Moreover, the computing system is configured to receive a second input associated with a turn being made or to be made by the sprayer. Additionally, the computing system is configured to determine a maximum ground speed for the turn at which a selected nozzle dispenses the agricultural fluid onto the field at the target application rate based on the received first and second inputs. Furthermore, when the turn is being made, the computing system is configured to control an operation of the sprayer such that the ground speed of the sprayer is at or below the determined maximum ground speed.

In a vehicle, GV control and M+ control are executed by generating braking/driving forces from a brake hydraulic pressure control device and a drive device during steering. A controller estimates (calculates), by a posture estimation unit, a pitch amount and a roll amount (predicted pitch rate and predicted roll rate) that occur in the vehicle through use of a moment command of the M+ control and a longitudinal G command of the GV control. The controller adjusts damping forces of damping force variable dampers through use of the estimated pitch amount and the estimated roll amount (predicted pitch rate and predicted roll rate) so that a pitch amount calculated by a pitch control unit and a roll amount calculated by a roll suppression unit approach respective target values.

Provided is a vehicle control device including: a storage device storing a program; and a hardware processor executing the program stored in the storage device to: recognize a surrounding situation of a vehicle; determine whether or not the surrounding situation includes a road division line; control steering and acceleration/deceleration of the vehicle; determine a driving mode of the vehicle as any one of a plurality of driving modes including a first driving mode and a second driving mode; and set, when the vehicle is traveling in the second driving mode, the surrounding situation is determined not to include a road division line, and a preceding vehicle is recognized within a first predetermined distance in a traveling direction of the vehicle, a longer traveling continuation distance in the second driving mode using the map information.