A backdoor includes a resin outer panel having an opening; a resin inner panel; a metal reinforcement arranged between the outer panel and the inner panel; and a rear glass covering the opening. The rear glass includes a defogger, and an antenna conductor capable of receiving radio waves in an AM band. The antenna conductor includes a power feeding part, and an antenna element having a predetermined length and connected to the power feeding part. The antenna element includes a proximity part extending along an outer edge among upper, lower, left, and right outer edges of the defogger, and having a predetermined spacing from the outer edge. The antenna element is positioned to be separated from the reinforcement by a predetermined spacing, or positioned on a side with respect to the outer edge where the reinforcement is not present in plan view of the rear glass.

A backdoor includes a resin outer panel having an opening; a resin inner panel; a metal reinforcement arranged between the outer panel and the inner panel; and a rear glass covering the opening. The rear glass includes a defogger, and an antenna conductor capable of receiving radio waves in an AM band. The antenna conductor includes a power feeding part, and an antenna element having a predetermined length and connected to the power feeding part. The antenna element includes a proximity part extending along an outer edge among upper, lower, left, and right outer edges of the defogger, and having a predetermined spacing from the outer edge. The antenna element is positioned to be separated from the reinforcement by a predetermined spacing, or positioned on a side with respect to the outer edge where the reinforcement is not present in plan view of the rear glass.

A tempering frame for thermal tempering of glass panes, includes a carrier frame and a support frame that is joined to the carrier frame via a plurality of connection elements and is arranged completely within the carrier frame, wherein the support frame has an upper primary surface for placing a glass pane, a lower primary surface, a front edge, and a rear edge, and wherein the support frame has recesses introduced in the rear edge, which are arranged between adjacent connection elements.

A vehicular rear slider window assembly includes an upper rail and a lower rail and a fixed window panel. The rails are attached at an inner surface of the fixed window panel above and below an opening. First and second movable window panels are movable along the rails. The drive system includes a drive element at the first movable window panel, a gear element rotatably mounted at a rail of the window assembly, and first and second toothed tracks attached at the respective movable window panel and extending toward and overlapping the other movable window panel. When the drive system is operated, the drive element imparts movement of the first movable window panel along the rails. Movement of the first movable window panel causes a corresponding movement of the second movable window panel in an opposite direction along the rails via engagement of the gear element with the toothed tracks.

An automotive rear window glazing for installation in a car, comprises at least two plies of glazing material and at least one ply of plastics interlayer material extending between the plies of glazing material, the ply of plastics interlayer material being substantially co-extensive with the plies of glazing material and bonding the plies of glazing material to each other, wherein the ply of plastics interlayer material contains draw lines extending in substantially one direction, the automotive rear window glazing has a top edge and a bottom edge, and wherein the automotive rear window glazing is installed with the draw lines in the plastics interlayer material extending from the top to the bottom edges.

The present disclosure provides a method comprising receiving a rideshare request from a user, the rideshare request including a destination; transporting the passenger to the destination using an autonomous vehicle (AV) having a plurality of windows comprising electrically switchable smart glass; during the transporting, monitoring a metric related to arrival of the AV at the destination; and untinting the windows when the monitored metric has a prescribed relationship to a threshold value.

The present disclosure provides a method comprising receiving a rideshare request from a user, the rideshare request including a destination; transporting the passenger to the destination using an autonomous vehicle (AV) having a plurality of windows comprising electrically switchable smart glass; during the transporting, monitoring a metric related to arrival of the AV at the destination; and untinting the windows when the monitored metric has a prescribed relationship to a threshold value.

A vehicle top can comprise a targa top and a retractable top. The retractable top can comprise fabric and a frame. The targa top and the retractable top can be configured to be coupled to a vehicle such that the targa top overlies at least one front seat of the vehicle and the retractable top is pivotable between deployed and retracted positions. The fabric of the retractable top can be disposed closer to the targa top and overlie more of the vehicle when the retractable top is in the deployed position than when the retractable top is in the retracted position.

A vehicle window unit that includes side curved regions that are arranged, in the installed state, near a, in particular standing, pillar of the vehicle body, wherein the curved regions are at least partially coloured in a transmittance reducing manner. The degree of colouration correlates with the degree of curvature.

A vehicle window unit that includes side curved regions that are arranged, in the installed state, near a, in particular standing, pillar of the vehicle body, wherein the curved regions are at least partially coloured in a transmittance reducing manner. The degree of colouration correlates with the degree of curvature.