The present disclosure relates to a crash pad device for a vehicle with a real wood sheet, the crash pad device including a real wood sheet comprising a real wood design portion having a real wood pattern processed thereon, and an edge portion formed at an edge of the design portion, and a lighting portion disposed at a lower side of the real wood sheet and being configured to emit light to an outside through the real wood pattern.

In one embodiment, a cognitive load driving assistant increases driving safety based on cognitive loads. In operation, the cognitive load driving assistant computes a current cognitive load of a driver based on sensor data. If the current cognitive load exceeds a threshold cognitive load, then the cognitive load driving assistant modifies the driving environment to reduce the cognitive load required to perform the primary driving task and/secondary task(s), such as texting via a cellular phone. The cognitive load driving assistant may modify the driving environment indirectly via sensory feedback to the driver or directly through reducing the complexity of the primary driving task and/or secondary tasks. In particular, if the driver is exhibiting elevated cognitive loads typically associated with distracted driving, then the cognitive load driving assistant modifies the driving environment to allow the driver to devote appropriate mental resources to the primary driving task, thereby increasing driving safety.

A vehicular display control apparatus includes: a condition determination portion that determines whether a deviation prediction condition has been established, the deviation prediction condition being a condition based on which a deviation between a sensible speed for a driver and an actual traveling speed is predicted; a speed difference determination portion that determines whether a speed difference between the actual traveling speed and a speed limit is a switching determination value or larger, and whether a shortage of the traveling speed from the speed limit is the switching determination value or larger; and a switching control portion that switches a speed display indicating the traveling speed to an emphasized display in a case when the condition determination portion determines that the deviation prediction condition has been established, and also when the speed difference determination portion determines that the speed difference is the switching determination value or larger.

The techniques of this disclosure relate to a vehicle occupancy-monitoring system. The system includes a controller circuit that receives occupant data from an occupancy-monitoring sensor of a vehicle. The controller circuit determines an occupancy status of respective seats in a cabin of the vehicle based on the occupancy-monitoring sensor. The controller circuit indicates the occupancy status of the respective seats on a display located in a field of view of occupants of the vehicle. The display is integral to one of a roof light module, a door panel, or a headliner of the cabin. The system can improve passenger safety by alerting the operator and other occupants about the occupancy status of the passengers.

A vehicle display control device includes a memory and a processor coupled to the memory. The vehicle display control device is configured such that the processor controls a vehicle display device for displaying an image on a display region so as to be superimposed on a portion of a view ahead of a vehicle. The processor is configured so as to detect a preceding vehicle traveling at a vehicle front side of a host vehicle, and in cases in which the preceding vehicle has been detected, causes an image that includes a plurality of inter-vehicle marker objects from the host vehicle side toward the preceding vehicle side to be displayed in the display region, and causes sequential emphasis display of the plurality of inter-vehicle marker objects in sequence from the host vehicle side toward the preceding vehicle side.

A display control device for a vehicle that is configured to: detect a target ahead of a vehicle; set an apparent angle of a marker relative to a reference plane in accordance with a distance between the target and the vehicle, the reference plane being related to a road surface on which the vehicle is traveling; and display the marker so as to be superimposed on the target as viewed by a driver of the vehicle.

A head-up display system for a vehicle includes at least one light source adapted to project an image upon an inner surface of a windshield of the vehicle, a driver monitoring system adapted to track a position of a driver's eyes, at least one non-visual sensor adapted to detect objects within an environment surrounding the vehicle, at least one image capturing device adapted to capture images of the environment surrounding the vehicle, and, a controller in communication with the at least one laser, the at least one non-visual sensor and the at least one image capturing device, the controller adapted to identify lane markers and objects within the environment surrounding the vehicle, determine the position of the vehicle within a lane of a roadway the vehicle is traveling upon, and, display, with the at least one light source, a lane position alert.

An automatic fill control system on a material loading vehicle generates an output indicative of a current fill level of a receiving vehicle into which the material loading vehicle is loading material. A fill level processing system generates a fill parameter indicative of when the receiving vehicle will reach a target capacity. The fill parameter is communicated to a mobile application on a mobile device in a receiving vehicle.

An autonomous vehicle is provided with a touch panel that enables an operator to input vehicle speed control instructions during an automatic driving mode and a mechanical operation unit for inputting driving control instructions. When the driving mode of the autonomous vehicle is the automatic driving mode or a semi-automatic driving mode, a driving control unit of the autonomous vehicle prioritizes a vehicle speed control instruction input from the touch panel over a vehicle speed control instruction input from the mechanical operation unit and executes vehicle speed control for the autonomous vehicle based on the prioritized instruction.

A working vehicle includes: a clutch displaceable to a connected state in which power is transmitted to a drive, a disconnected state in which the transmission is disconnected, and a half-clutch state in which power is slidably and partly transmitted to the drive; a detector that detects an operation position of a clutch pedal and outputs a detected value corresponding to the operation position detected; a control device that brings the clutch into the half-clutch state if the detected value corresponds with a threshold, and brings the clutch into the disconnected state if the detected value is less than the threshold and into the connected state if the detected value is greater than the threshold, and vice versa; and a change unit that changes the threshold to a different value in accordance with an operation on the operation member.