In a vehicle camera device, engaging claws of a base are passed through through-holes of a camera mechanism and insertion pins of a second cover are inserted in insertion holes that are within the engaging claws, such that the through-holes are positioned with respect to the engaging claws and the insertion pins are positioned with respect to the insertion holes. Therefore, the camera mechanism and the second cover can be positioned with respect to the base, and a lens of the camera mechanism and an opening of the second cover can be aligned well.

In a vehicle camera device, engaging claws of a base are passed through through-holes of a camera mechanism and insertion pins of a second cover are inserted in insertion holes that are within the engaging claws, such that the through-holes are positioned with respect to the engaging claws and the insertion pins are positioned with respect to the insertion holes. Therefore, the camera mechanism and the second cover can be positioned with respect to the base, and a lens of the camera mechanism and an opening of the second cover can be aligned well.

The optical assembly disclosed in the embodiment includes a housing having an inclined bottom surface, a plurality of inner surfaces around an outer periphery of the bottom surface, and a receiving space in which an upper portion is opened; and a lighting module disposed on the inclined bottom surface, wherein the lighting module includes a substrate inclinedly disposed on the inclined bottom surface; at least one light emitting device disposed on the substrate; and a resin layer sealing the light emitting device and the substrate, wherein an upper surface of the resin layer emits light by diffusing light emitted from the light emitting device, wherein the plurality of inner surfaces includes a first inner surface adjacent to the light emitting device, a second inner surface facing the first inner surface, and third and fourth inner surfaces facing each other and disposed between the first and second inner surfaces, wherein a height between the bottom surface of the housing and an upper surface of the housing increases from the first inner surface toward the second inner surface, and decreases from the third inner surface toward the fourth inner surface.

The optical assembly disclosed in the embodiment includes a housing having an inclined bottom surface, a plurality of inner surfaces around an outer periphery of the bottom surface, and a receiving space in which an upper portion is opened; and a lighting module disposed on the inclined bottom surface, wherein the lighting module includes a substrate inclinedly disposed on the inclined bottom surface; at least one light emitting device disposed on the substrate; and a resin layer sealing the light emitting device and the substrate, wherein an upper surface of the resin layer emits light by diffusing light emitted from the light emitting device, wherein the plurality of inner surfaces includes a first inner surface adjacent to the light emitting device, a second inner surface facing the first inner surface, and third and fourth inner surfaces facing each other and disposed between the first and second inner surfaces, wherein a height between the bottom surface of the housing and an upper surface of the housing increases from the first inner surface toward the second inner surface, and decreases from the third inner surface toward the fourth inner surface.

A mirror assembly can include a housing, a mirror, and a light source. In certain embodiments, the mirror is rotatable within a support portion of the mirror assembly. In some embodiments, the mirror assembly is configured to use an audio sensor or an audio signal derived from an audio sensor, such as an audio sensor or audio signal configured to sense or to correspond to or to represent one or more voice commands or other sounds (e.g., clapping, snapping, or otherwise) received from a user, in order to actuate or adjust any of one or more features or settings of the mirror assembly.

A rearview assembly includes an electrochromic element. The electrochromic element includes a first substrate including a first surface and a second surface. The electrochromic element further includes a second substrate comprising a third surface and a fourth surface. The first substrate and the second substrate form a cavity. The electrochromic element includes an electrochromic medium contained in the cavity. The rearview assembly includes an image sensor directed toward the fourth surface and configured to capture near-infrared light reflected from an object and projected through the electrochromic element. The rearview assembly includes a transflective film disposed adjacent to the fourth surface having a near-infrared light transmission level and a visible light reflectance level.

A rearview assembly includes an electrochromic element. The electrochromic element includes a first substrate including a first surface and a second surface. The electrochromic element further includes a second substrate comprising a third surface and a fourth surface. The first substrate and the second substrate form a cavity. The electrochromic element includes an electrochromic medium contained in the cavity. The rearview assembly includes an image sensor directed toward the fourth surface and configured to capture near-infrared light reflected from an object and projected through the electrochromic element. The rearview assembly includes a transflective film disposed adjacent to the fourth surface having a near-infrared light transmission level and a visible light reflectance level.

Provided is an input unit to which input signals are inputted, the input signals including signals indicating operating states of switches used for operating the electronic mirror and used for selecting a display mode from among the plurality of display modes to be displayed by the electronic mirror; a storage unit that together with prioritizing and storing each of a plurality of display modes in a hierarchical structure, stores mode setting conditions that are conditions for setting each display mode; a determination unit for determining whether or not the mode setting conditions are satisfied for each of the plurality of display modes based on the input signals; and a setting unit that, of the plurality of display modes, sets a display mode from among the display modes for which the mode setting conditions are satisfied, as a display mode to be displayed on the electronic mirror.

A rearview mirror assembly includes a mirror element including a first substrate having a first surface and a second surface. A reflector is disposed adjacent to one of the first and second surfaces. The rearview mirror assembly further includes a lighting subassembly includes a light source and a diffuser. The light source is operable to project light through the mirror element. The diffuser is disposed between the light source and the mirror element. The light source comprises a plurality of micro light-emitting diodes arranged in a light shape representing a display icon such that the display icon is projected through the mirror element without any influence on the shape caused by any other component of the mirror element.

A rear view system for a vehicle includes: a transmitter configured to transmit a transmitter signal; a receiver configured to receive the transmitter signal and transmit information on whether the transmitter signal is received; a rear camera configured to capture a rear view of the vehicle, and transmit an image for the captured rear view of the vehicle; one or more displays mounted within the vehicle; and a controller configured to receive an image for a rear view of the vehicle from the rear camera in response to the reception of information indicating that the transmitter signal is not received from the receiver, and display the received image for the rear view of the vehicle on the one or more displays.