A display control device includes a hardware processor. The hardware processor implements functions of a first operating system, a second operating system, and a hypervisor. The first operating system controls execution of at least one of a first application and a second application. The first application serves to generate a first content image to be displayed on a first display device mounted on a vehicle. The second application serves to generate a second content image to be displayed on a second display device mounted on the vehicle. The second operating system is different from the first operating system. The hypervisor controls execution of the first operating system and the second operating system.

A vehicle interior panel includes an in-vehicle support substrate and a docking station for a mobile device. The docking station includes a top edge, a bottom wall, and a reception surface for the mobile device between the top edge and the bottom wall. The reception surface is pivotably attached with respect to the support substrate. A first portion of the bottom wall is configured to hold the mobile device, and a second portion of the bottom wall is configured to remain recessed within the support substrate when the docking station is in a tilted position. This structure for a docking station helps improve within vehicle integration.

A vehicle interior assembly includes a foldable layer that is convertible between an unfolded condition, in which it provides the working surface of a tabletop, and a folded condition, in which it supports one or more portable electronic devices in a tilted position. When deployed as part of a device holder, the foldable layer uncovers a portion of a base layer that includes edge supports for the mobile device(s). A plurality of polygonal segments interconnected by a corresponding plurality of hinge joints permits the foldable layer to change from a flat sheet to a hollow, self-supporting three-dimensional structure with a clean angular appearance in an origami-like manner that does not require complex linkages or mechanisms for the conversion.

An electronic equipment device includes a microphone member and a cap. The microphone member is positioned in a through hole of a roof lining provided in a vehicle interior and disposed in an indoor space, and disposed in an outdoor space. The cap is positioned in the through hole of the roof lining and fitted to the microphone member in a state of being disposed in the indoor space. The cap has a fitting portion, a strap portion, and a hooking portion. The fitting portion is fitted to the microphone member. The strap portion is provided in the outdoor space. The hooking portion is formed in the strap portion and hooked on the microphone member.

A head-up display for a vehicle in which an assembly structure of a screen and a picture generation unit (PGU) is reinforced. The head-up display for a vehicle according to one embodiment includes a lower case embedded with a board assembly, and a screen connected to the lower case in a plurality of directions and snap-fit-coupled to the lower case by passing through the board assembly in at least one direction.

A vehicle and a controlling method of the same include a speaker outputting virtual engine sound integrated with a head lamp. The vehicle includes the head lamp; a head lamp case in which the head lamp is provided; and a speaker for outputting a virtual engine sound, and provided inside the head lamp case, where an internal cross-sectional area of the head lamp case may increase in a direction toward a front of the vehicle based on a position where the speaker is provided.

A system includes a microphone unit coupled to a roof of an autonomous vehicle. The microphone unit includes a microphone board having a first opening. The microphone unit also includes a first microphone positioned over the first opening and coupled to the microphone board. The microphone unit further includes an accelerometer. The system also includes a processor coupled to the microphone unit.

A system includes a microphone unit coupled to a roof of an autonomous vehicle. The microphone unit includes a microphone board having a first opening. The microphone unit also includes a first microphone positioned over the first opening and coupled to the microphone board. The microphone unit further includes an accelerometer. The system also includes a processor coupled to the microphone unit.

In at least some implementations, an accessory mount for a vehicle includes a first base, a support and a connector coupling the support to the first base. The first base has a first retainer with one or more retention features. The support has a second retainer that has one or more retention features that overlap one or more of the one or more retention features of the first retainer in different positions of the support relative to the first base. At least one of the first retainer and second retainer is movable relative to the other to decouple the first retainer and second retainer without removing the connector from the first base to enable movement of the support to multiple positions relative to the first base.

A vehicle includes: a frame including a roll cage, a motor connected to the frame, a driver seat connected to the frame, and a roof extending at least in part above the driver seat. The roof includes an upper surface and a lower surface. At least part of the roof is pivotably connected to the roll cage about a roof pivot axis so that the at least part of the roof is pivotable from a closed position to an open position. In the closed position, the at least part of the roof covers a roof opening defined by the roll cage, and in the open position, the at least part of the roof at least partly exposes the roof opening.