Methods and systems for improving vehicular safety by utilizing uplift modeling techniques to improve a driving tip treatment generation model are provided. According to embodiments, a tip server can analyze telematics data associated with operation of one or more vehicles to determine that a driving tip should be provided to a driver of a vehicle. The tip server then utilize a treatment generation model to determine a treatment for how to provide the driving tip in a manner optimized for the particular driver. The tip server can analyze additional telematics data to determine an effectiveness of the driving tip and to update the treatment generation model in accordance with uplift modeling techniques.

An on-vehicle device includes a display device, a body device, and a support plate. The body device is installed on a back surface of the display device. The support plate includes a fixation part with a plate shape that is fixed on a top surface of the body device and a support part with a plate shape that is continuous with the fixation part and is formed so as to be bent, and supports a back surface of the display device by a plate spring part that is formed on the support part.

Redundant vehicle controls based on user presence and position are disclosed herein. A method can include determining a presence and a position of a driver in a sensing zone of a vehicle using a sensor platform integrated into the vehicle. The sensing zone is associated with a primary driving interface of the vehicle. Determining when the position of the driver indicates that the driver is not in a fully-seated position relative to a driver's seat of the vehicle, and that the vehicle is in a non-seated drive mode where the driver is permitted to operate the vehicle while not being in the fully-seated position. Activating a secondary driving interface of the vehicle when the driver is not in a fully-seated position and the vehicle is in the selected driving mode. The secondary driving interface can be used in combination with the primary driving interface.

A vehicle includes a steering wheel support assembly that includes a trim component that defines a trough. The vehicle further includes a steering wheel operably coupled to the steering wheel support assembly and operable to pivot about a first axis from a steering wheel use position to a steering wheel stowed position. In the steering wheel use position, the steering wheel is operable to rotate about a second axis to steer the vehicle. In the steering wheel stowed position, a portion of the steering wheel is received within the trough defined by the trim component.

A vehicle includes a steering wheel support assembly that includes a trim component that defines a trough. The vehicle further includes a steering wheel operably coupled to the steering wheel support assembly and operable to pivot about a first axis from a steering wheel use position to a steering wheel stowed position. In the steering wheel use position, the steering wheel is operable to rotate about a second axis to steer the vehicle. In the steering wheel stowed position, a portion of the steering wheel is received within the trough defined by the trim component.

A utility vehicle includes an open driver section including a driver’s seat for a driver to sit on; a hermetically sealable space disposed in the driver section and having a door; and a terminal in the hermetically sealable space.

A utility vehicle includes an open driver section including a driver’s seat for a driver to sit on; a hermetically sealable space disposed in the driver section and having a door; and a terminal in the hermetically sealable space.

An instrument panel assembly for a vehicle includes an instrument panel body including a driver-side portion, a center stack portion, and a passenger-side portion. A cross-car beam assembly is configured to at least partially support the instrument panel body and includes a horizontal member extending across at least the passenger-side portion of the instrument panel body. A first lower reinforcement bracket is spaced apart from the horizontal member and extends across the passenger-side portion of the instrument panel body. A second lower reinforcement bracket is coupled with the first lower reinforcement bracket. A vertical reinforcement bracket extends between the horizontal member and the first and second lower reinforcement brackets. The vertical reinforcement bracket includes a curved portion proximate a first end and coupled with the horizontal member. A second end of the vertical reinforcement bracket is coupled with at least one of the first and second lower reinforcement brackets.

The invention provides device, system, and method for projecting light in the interior of an automotive vehicle. The method includes sending data to the light projector regarding the lighting conditions in the interior of the automotive vehicle, using the data to modify some projection parameter of a light pattern, and projecting the light pattern.

Electrostatic friction textures on a touchscreen panel are used to create the sensation of block icons in a contextual menu adapted to an automotive environment. In particular, a center stack touchscreen friction display in a passenger vehicle provides one set of touch controls and HMI data to the driver while simultaneously providing either the same control options and HMI or a completely different set of information and menu structure to the passenger in invisible texture form. The invisible texture is in the form of block icons, and coincidence between a finger of a passenger and a block icon results in an audio announcement of the block icon to guide a visually impaired passenger through the contextual menu.