A display device includes: a sensor, a display, and a processor. The processor is configured to set a primary user of the display, detect a hand of a user using the sensor, determine whether the detected hand is a hand of the primary user, based on the determination that the detected hand is the hand of the primary user, execute a first function according to a first movement of the detected hand, and control the display to display information corresponding to the first function.

A display apparatus and a vehicle including the same are provided. A display apparatus includes: a display panel configured to display an image, a driving circuit including: a flexible circuit film connected to the display panel, and a printed circuit board connected to the flexible circuit film, a first supporting member at a rear surface of the display panel, the first supporting member having a hole therein, and a vibration apparatus supported by the first supporting member, the vibration apparatus including a first vibration apparatus disposed at the rear surface of the display panel, wherein the flexible circuit film extends through the hole, and wherein the printed circuit board is disposed at a rear surface of the first supporting member.

An apparatus for controlling a cluster of a vehicle may include, an oil pressure switch (OPS) mounted at an oil passage of an engine, a driving information detection unit configured of receiving an oil pressure signal from the OPS through a connector of the OPS, an OPS connection determination unit configured of determining that the OPS is disconnected when a first waveform voltage determined from a first oil pressure signal detected before the engine is started is the same as a second waveform voltage determined from a second oil pressure signal detected after the engine is started, and a control unit configured of controlling the cluster to turn on a warning lamp in a response that the control unit receives disconnection event information related to the OPS.

The disclosure relates to a method for displaying output data, wherein the output data includes motor-vehicle-side data of a motor vehicle which is displayed via a placard, wherein the motor-vehicle-side data is represented by a color coding of the placard and approval data of the motor vehicle, said method comprising the following steps: providing a display device for displaying the output data; detecting the motor-vehicle-side data of the motor vehicle by means of a detection device; determining the color coding of the placard by means of a control device based on the detected motor-vehicle-side data; displaying a placard surface of the placard in a display region of a display surface of the display device, wherein the placard surface has the color coding; and receiving a release signal for displaying the approval data in a predetermined region of the placard surface of the placard.

A vehicle control device incorporating at least one vehicle control element and a vehicle terminal is disclosed, the at least one vehicle control element being adapted to control a functionality of a vehicle implement or tool, the vehicle terminal incorporating a terminal display, the terminal display being adapted to alter the functionality of the vehicle implement or tool associated with the vehicle control element, the terminal display also indicating the functionality associated with the vehicle control element, wherein the vehicle control element incorporates a vehicle control display element, the vehicle control display element indicating whether the functionality of the vehicle control element has been altered. This enables a driver when looking at the vehicle control element easily to see from the vehicle control display element whether the functionality of the vehicle control element has been altered.

A vehicular blind spot detection system for alerting a driver of a motor vehicle to an object in a blind spot zone of the vehicle includes a sensor configured to detect the presence of an object proximate to the vehicle in the blind spot zone. A first indicator is disposed on an outside rearview assembly and is configured to indicate that an object is in the blind spot zone of the vehicle. A controller is operably coupled with at least one of the sensor and the first indicator, wherein the controller may be activated and deactivated by a user. A second indicator is disposed proximate the first indicator and is configured to indicate that the controller has been deactivated.

An earth working machine (10), having a propelling unit (22) and a machine frame (12) carried by the propelling unit (22), comprises a working apparatus (32) for earth working; an operator's platform (24), having an operating console (26) comprising a console body (52) and an operating panel (54, 66) that is movable relative to the console body (52) and has at least one operating element (58) associated or associatable with a functional device (32, 39) for control thereof. The operating panel (54, 66) is displaceable into a stowed position in which the at least one operating element (58) is covered by a portion (56a, 72a) of the console body (52.

A spatial infotainment rendering system may include at least one infotainment device configured to present information to a vehicle occupant traveling along a vehicle route at one of a plurality of infotainment locations within the vehicle and at least one spatial rendering processor. The processor may be configured to receive vehicle location and direction information of the vehicle along the vehicle route, receive event data indicative of an event having a potential to affect the vehicle route, and determine an event location based on event data. The processor may also be configured to select one of the infotainment locations based on the event location relative to the vehicle location and direction to present event information to the vehicle occupant relating to the event at a location spatially related to the event location relative to the vehicle route.

Techniques are disclosed for creating and presenting a graphical user interface for display of autonomous vehicle behaviors. The techniques include determining a trajectory of a vehicle operating in a real-world environment. Sensors of the vehicle obtain sensor data representing an object in the real-world environment. A maneuver of the vehicle to avoid a collision with the object is predicted based on the sensor data and the trajectory of the vehicle. It is determined that a passenger comfort level of a passenger riding in the vehicle will decrease based on the maneuver of the vehicle. The passenger comfort level is measured by passenger sensors of the vehicle. A graphical user interface is generated including representations of the vehicle, the object, and a graphic, text, or a symbol alerting the passenger of the predicted maneuver. The graphical user interface is transmitted to a display device of the vehicle.

A display device has a display portion and a polarizing plate, the polarizing plate being provided on a viewing side of the display portion and having a transmission axis in a vertical direction with respect to the display portion, wherein at least one tilt orientation phase difference film is provided on a viewing side of the polarizing plate, and the tilt orientation phase difference film has such an arrangement structure that does not cause a phase difference for light emitted upward in the vertical direction, and causes a phase difference for light emitted in a lateral direction perpendicular to the vertical direction.