Systems and methods for operating a vehicle that includes an engine that may be automatically stopped and started are described. In one example, an engine may be automatically stopped in response to an electric assisted braking threshold level that is adjusted responsive to vehicle speed so that opportunities to automatically stop an engine may be increased, thereby conserving fuel.

Systems and methods for hybrid actuator system control are disclosed herein. The system can include a simulation vehicle. The simulation vehicle can transit at least one passenger through a ride experience, can include a plurality of controls, and can be mounted on an actuator system controllable to move the simulation vehicle in connection with at least one ride event. The system can include a processor. The processor can: provide content to the at least one passenger; receive user inputs via the plurality of controls of the simulation vehicle; identify authored control data; generate algorithmic control data; generate a hybrid control signal according to a combination of the authored control data and the algorithmic control data; and control movement of the simulation vehicle according to the hybrid control signal.

Systems and methods for operating a vehicle that includes an engine that may be automatically stopped and started are described. In one example, an engine may be automatically stopped in response to an electric assisted braking threshold level that is adjusted responsive to vehicle speed so that opportunities to automatically stop an engine may be increased, thereby conserving fuel.

Systems and methods for operating a vehicle that includes an engine that may be automatically stopped and started are described. In one example, an engine may be automatically stopped in response to an electric assisted braking threshold level that is adjusted responsive to vehicle speed so that opportunities to automatically stop an engine may be increased, thereby conserving fuel.

A method of controlling a transmission includes determining a transmission kinematic state based on a commanded transmission gear range, a transmission input speed, and a transmission output speed, determining a transmission input torque, determining a first rotational acceleration of a first portion of the transmission rotationally disposed at a first reference point in the transmission, determining a second rotational acceleration of a second portion of the transmission rotationally disposed at a second reference point in the transmission, and determining a transmission output torque as a sum of a gear ratio of the commanded transmission gear range multiplied by the transmission input torque, a first aggregate inertia multiplied by the first rotational acceleration, and a second aggregate inertia multiplied by the second rotational acceleration, wherein the first and second aggregate inertias are based on the transmission kinematic state.

The invention relates to a method for setting a driving speed of a motor vehicle on a route. A control device of the motor vehicle sets the driving speed depending on an operating position limited by two extreme positions of a pedal device of the motor vehicle, which may be operated by a driver, wherein the control device detects the operating position of the pedal device, and depending on the detected operating position, determines in at least one specified driving mode a target driving speed corresponding to the respective operating position, and the control device sets the driving speed corresponding to the respective target driving speed by means of a closed loop control as long as the respective operating position is detected. The setting in this case takes place independently of a current condition of the route. The invention also includes a motor vehicle.

A vehicle control station includes a hand rest and at least one micro-joystick positioned relative to the hand rest such that the hand rest is configured to locate an operator's hand and fingers in position to operate the at least one micro-joystick. A function enable switch is configured to activate the at least one micro-joystick.

A vehicle control station includes a hand rest and at least one micro-joystick positioned relative to the hand rest such that the hand rest is configured to locate an operator's hand and fingers in position to operate the at least one micro-joystick. A function enable switch is configured to activate the at least one micro-joystick.

A system for controlling a work vehicle towing an agricultural implement having ground-engaging tools across a field includes a vehicle controller configured to control operation of the work vehicle, an implement controller configured to control operation of the implement, and at least one sensor communicatively coupled to either or both of the vehicle controller and/or the implement controller. The vehicle controller and/or the implement controller is also programmed with a field map. The sensor(s) is configured to provide an indication of a location of the implement within the field. The implement controller is configured to perform one or more operations, including but not limited to anticipating a change in loading of one or more of the ground-engaging tools of the implement based on the location of the implement relative to the field map and transmitting a request instructing the vehicle controller to initiate a control action associated with adjusting at least one operational parameter of the work vehicle to accommodate the anticipated change.

A system for controlling a work vehicle towing an agricultural implement having ground-engaging tools across a field includes a vehicle controller configured to control operation of the work vehicle, an implement controller configured to control operation of the implement, and at least one sensor communicatively coupled to either or both of the vehicle controller and/or the implement controller. The vehicle controller and/or the implement controller is also programmed with a field map. The sensor(s) is configured to provide an indication of a location of the implement within the field. The implement controller is configured to perform one or more operations, including but not limited to anticipating a change in loading of one or more of the ground-engaging tools of the implement based on the location of the implement relative to the field map and transmitting a request instructing the vehicle controller to initiate a control action associated with adjusting at least one operational parameter of the work vehicle to accommodate the anticipated change.