When the automobile is changed to the manual driving mode, the control device starts acceptance as the operation of the touch pad as an operation on the application system that displays the screen on the heads-up display, and when the automobile is in the autonomous driving mode, the control device starts acceptance of the operation of the touch pad as an operation on the application system that displays the screen on the center display.

A device for luminously signalling a change of lane for a motor vehicle comprises at least one element for detecting the change of lane of the vehicle and at least one control module configured to receive and process information coming from the one or more elements for detecting the change of lane and to accordingly control at least one emitting and projecting element configured to project at least one pictogram onto the road.

A virtual human-machine interface system for a vehicle including at least one projection surface disposed within the vehicle and a corresponding virtual human-machine interface method for a vehicle are provided. The virtual human-machine interface system comprises at least one micro-mirror projection device for projecting an image on the at least one projection surface, at least one sensor for detecting commands given by a user by determining the position of a part of the user's body within the vehicle, and a control unit for controlling the human-machine interface system. The position of the image projected by the at least one projection device within the vehicle may be modified by a specific command given by the user.

A vehicle head-up display includes a liquid crystal panel, a light source, a first polarizing panel, and a second polarizing panel. The liquid crystal panel has opposing input and output surfaces. The liquid crystal panel is configured to form an image oriented relative to a horizontal axis. The light source is configured to direct light toward the input surface, through the liquid crystal panel, and out of the output surface to project the image onto an interior surface of a vehicle windshield. The first polarizing panel is secured to the output surface and has a first polarization axis oriented at a first angle relative to the horizontal axis. The second polarizing panel is disposed between the first polarizing panel and the windshield. The second polarizing panel has a second polarization axis oriented oriented at a second angle relative to the horizontal axis.

Methods described herein relate to using vision-based mapping to provide augmented reality of objects in the environment of the vehicle in response to objects being obscured. Methods may include: receiving sensor data from a vehicle traveling along a road segment; identifying a location of the vehicle on the road segment; retrieving map data from a map database of an environment of the road segment at the location of the vehicle on the road segment; identifying an object in the sensor data representing an obscured object in an environment of the vehicle; and providing for display of at least one object from the map data in an augmented reality of the environment, where the at least one object appears overlaid on the obscured object to a driver of the vehicle. The object in the sensor data may include a road sign having information relating to driving along the road segment.

In described examples, an image-generating panel is arranged for modulating a projection beam to include a modulated optical image. A cooling device is arranged to transfer heat received from the image-generating panel to a heat sink. The cooling device is arranged to receive the projection beam on a first side and to transmit the projection beam from a second side. The heat received from the image-generating panel can include heat generated by the image-generating panel in response to incidental sunlight.

Systems, apparatus and methods for limiting information on an augmented reality (AR) display based on various speeds of an AR device are presented. Often information forms a distraction when the wearer is driving, running or even walking. Therefore, the described systems, devices and methods aim to limit information displayed on an AR display based on three or more levels movement (e.g., stationary, walking, driving) such that the wearer is less distracted when higher levels of concentration are needed for real world activities.

A vehicle is provided that detects a first presence of a driver in a vehicle, based upon detecting the first presence, provides a user interface for the driver to enter first user information, information, and communicates the first sensitive information to a vendor to authenticate the combines the first user information and the vehicle information to generate the first sensitive driver to enable the vendor to perform a financial transaction with the driver using the first sensitive information while the vehicle is in motion. The processor is programmed to initiate automatically, on behalf of the driver, the financial transaction with the vendor in response to a sensed state or location of the vehicle.

An angle-adjusting mechanism is provided. The angle-adjusting mechanism includes a reflecting assembly, a transmission assembly and a driving unit. The reflecting assembly includes a reflecting plate. The transmission assembly includes a transmission rod and a connecting element disposed on the transmission rod. The transmission assembly is connected to the reflecting assembly via the connecting element. The driving unit is configured to drive the transmission rod to move the reflecting assembly.

A method and an illumination arrangement for generating image effects in the interior of a motor vehicle or also outside the motor vehicle. To use existing installation space as efficiently as possible, light is radiated, in the form of at least a first optical reference wave field, onto a irradiation surface that is arranged laterally on an optical image storage device. In the optical image storage, which contains a holographic layer or a diffractive optical layer, the optical reference wave field is transformed into at least a first image wave field and is emitted on an emission side, at a first angular offset with respect to the irradiation surface.