Automotive glass structures having curves and feature lines and methods for forming the same are provided. An example method includes applying localized heat (e.g., via a laser, heating element) to a location of a substantially planar glass structure and bending the glass structure at that location (e.g., along a line of the planar glass structure) to form a feature line in the glass structure. The bending can be formed to have a radius of curvature of between 2 mm and 5 cm. Additional layers of curved or joined glass layers may further be included to form a curved multi-layer glass structure for automotive use.

Automotive glass structures having curves and feature lines and methods for forming the same are provided. An example method includes applying localized heat (e.g., via a laser, heating element) to a location of a substantially planar glass structure and bending the glass structure at that location (e.g., along a line of the planar glass structure) to form a feature line in the glass structure. The bending can be formed to have a radius of curvature of between 2 mm and 5 cm. Additional layers of curved or joined glass layers may further be included to form a curved multi-layer glass structure for automotive use.

A display device is disclosed. The device includes: a display that is provided to a moving body; and a display controller that controls displaying, on the display, of a virtual object corresponding to an object seen through the display from inside of the moving body, based on a positional relationship between the object and the moving body.

A display device, a display method, and a vehicle are disclosed. The device includes: a transmissive display that is provided to a moving body; and a display controller that changes transparency of the transmissive display based on traveling information on traveling of the moving body.

A method for electrically controlling a functional element with electrically controllable optical properties enclosed in a glazing unit includes controlling the optical properties by a control unit connected to two transparent flat electrodes of the functional element, and applying a voltage by the control unit between the flat electrodes and the polarity of the voltage is periodically changed. The voltage has a trapezoidal profile and by the control unit an increasing electrical voltage is applied for charging the functional element, the electrical voltage increasing to a first peak value, the electrical voltage is reduced from the first peak value to a final voltage for discharging the functional element, the functional element is charged with the increasing electrical voltage with reversed polarity, wherein the electrical voltage increases to a second peak value, the electrical voltage is reduced from the second peak value to the final voltage for discharging the functional element.

A method for electrically controlling a functional element with electrically controllable optical properties enclosed in a glazing unit includes controlling the optical properties by a control unit connected to two transparent flat electrodes of the functional element, and applying a voltage by the control unit between the flat electrodes and the polarity of the voltage is periodically changed. The voltage has a trapezoidal profile and by the control unit an increasing electrical voltage is applied for charging the functional element, the electrical voltage increasing to a first peak value, the electrical voltage is reduced from the first peak value to a final voltage for discharging the functional element, the functional element is charged with the increasing electrical voltage with reversed polarity, wherein the electrical voltage increases to a second peak value, the electrical voltage is reduced from the second peak value to the final voltage for discharging the functional element.

A vehicle window, includes at least one transducer device and transducer electronics associated with the transducer device, wherein both the transducer device and the transducer electronics are arranged at least partially within the vehicle window, wherein the transducer device and/or a compensating device associated with the transducer device and arranged at least partially within the vehicle window and/or an electrical shielding device associated with the transducer device for electrically shielding the transducer device relative to a vehicle interior or a vehicle exterior are transparent, at least in sections.

A vehicle window, includes at least one transducer device and transducer electronics associated with the transducer device, wherein both the transducer device and the transducer electronics are arranged at least partially within the vehicle window, wherein the transducer device and/or a compensating device associated with the transducer device and arranged at least partially within the vehicle window and/or an electrical shielding device associated with the transducer device for electrically shielding the transducer device relative to a vehicle interior or a vehicle exterior are transparent, at least in sections.

A windshield for a vehicle and a method for manufacturing the windshield are provided in the disclosure. The windshield includes an outer glass panel, an inner glass panel, and an intermediate adhesive layer. An opaque masking layer is disposed on at least one surface of the windshield. The opaque masking layer includes a dark ceramic-ink layer and an ultraviolet-drying ink layer. The dark ceramic-ink layer has a first no-ink region, the ultraviolet-drying ink layer is located in the first no-ink region, the ultraviolet-drying ink layer has a light transmitting region. According to the disclosure, an optical quality of the light transmitting region can be ensured, a diopter of the light transmitting region is less than or equal to 200 mdpt.

A windshield for a vehicle and a method for manufacturing the windshield are provided in the disclosure. The windshield includes an outer glass panel, an inner glass panel, and an intermediate adhesive layer. An opaque masking layer is disposed on at least one surface of the windshield. The opaque masking layer includes a dark ceramic-ink layer and an ultraviolet-drying ink layer. The dark ceramic-ink layer has a first no-ink region, the ultraviolet-drying ink layer is located in the first no-ink region, the ultraviolet-drying ink layer has a light transmitting region. According to the disclosure, an optical quality of the light transmitting region can be ensured, a diopter of the light transmitting region is less than or equal to 200 mdpt.