This work vehicle (tractor), which is provided with an engine and an accelerator pedal capable of changing the operational state of the engine, and is configured to be free to travel by means of an operation of the accelerator pedal by an operator, is equipped with a display near an operator's seat, said display being configured to be capable of displaying a screen (travel customization screen) for selecting whether or not to allow travel in conjunction with the accelerator.

A processor controls a first display section and a second display section provided to a vehicle such that when an occupant of the vehicle has performed a first operation while in a state in which a message is being displayed on the first display section and the second display section, the message is cleared from the first display section and the message continues to be displayed on the second display section.

A vehicle combining the attributes of a tractor and a utility vehicle includes a three point linkage and other locations to which a plurality of attachments for performing grooming or working operations on a ground or turf surface may be couple. The vehicle includes a front mounted engine, a mid-mounted operator compartment and a rear mounted bed or box. A PTO shaft and/or a hydraulic power system of the vehicle power attachments that require power. A control system and a visual display and data entry device linked thereto are provided for allowing an authorized person to setup, store and thereafter use an operational profile for each attachment that is to be coupled to the vehicle. In a rate dependent attachment, the control system maintains the ground speed and the attachment implement in a fixed ratio. A down/up control is used to signal the start and end of an operational sequence to the control system.

An instrument control system and method for utilizing backchannel bandwidth of a display channel to transmit data and commands to instruments. The system and method may be implemented with respect to a number of instruments disposed within a vehicle. The backchannel bandwidth may be utilized by a number of instruments forming an instrument cluster. The transmission of display data and instrument data may utilize a processor configured to deserialize data provided in a serialized format conforming to known digital protocol.

Data characterizing a relative arrangement of vehicle occupants with respect to one another are continuously transmitted to display devices worn on the heads of the vehicle occupants. Virtual environments are displayed as a function of these data.

The disclosure relates to a method for operating a motor vehicle, in which an operating device is used to receive a user input that characterizes a selection of an ambient mode to be set from multiple predefined ambient modes, and in which a control apparatus is used to trigger the setting of a group of settings, represented by the selected ambient mode, in vehicle components of the motor vehicle that are predefined by the selected ambient mode, that are to be set, and that each provide a comfort function.

One or more embodiments include techniques for automating vehicle routines. The techniques include receiving a rule that includes one or more deterministic elements and a machine learning element; collecting, during operation of the vehicle, a set of vehicle data based on the machine learning element; training a machine learning model that corresponds to the machine learning element using the set of vehicle data, wherein the machine learning model is used to process the machine learning element during execution of the rule.

A working machine has a display device including: an area display portion to display a setting area for setting the first priority value, the second priority value, and the third priority value; a first axis display portion including a first scale portion indicating the first priority value depending on a distance from the reference point; a second axis display portion including a second scale portion indicating the second priority value depending on a distance from the reference point; a third axis display portion including a third scale portion indicating the third priority value depending on a distance from the reference point; and a marker display portion to be indicated in a partial area corresponding to at least two of the first axis display portion, the second axis display portion, and the third axis display portion.

An operation device in which in-vehicle devices are controlled in accordance with a rotation angle of an input unit operated by a manual operation of a driver, which includes a commander rotatable about a rotation shaft, a rotation angular speed calculation unit that detects a rotation angular speed of the commander, a motor that gives an operation reaction force for each predetermined rotation angle of the commander, and an ECU that controls the operation reaction force given by the motor, wherein the ECU changes the operation reaction force in accordance with the rotation angular speed detected by the rotation angular speed calculation unit.

A trailed vehicle is provided comprising a plurality of operational components, at least one weight-sensing component, a body control module, a weight processing module, and an interface device comprising memory, a hardware processor coupled to the memory, a user interface, and a display. The user interface comprises user prompts for (i) associating particular operational components with the trailed vehicle and (ii) associating a particular weight-related parameter with the trailed vehicle. The weight processing module, the weight-sensing component, and the user interface are structured to generate an indication of vehicle weight at the user interface. The indication of vehicle weight is at least partially dependent upon the particular weight-related parameter associated with the trailed vehicle at the user interface. Additional embodiments are disclosed and claimed.