A base assembly of an exterior rear view device includes a base frame, and a base cover housing the base frame and formed in at least two parts connected to each other, where the base assembly includes a first opening at a first end of the base assembly at which the base frame is configured to be attached to a vehicle and a second opening at a second end of the base assembly at which a head assembly of the exterior rear view device is configured to be attached to the base frame.

Disclosed are a vehicle and a control method thereof configured for performing a vehicle control to detect lighting irradiated from a lamp at the time of vehicle parking and park the vehicle safely and accurately. The vehicle includes a lamp configured to irradiate lighting to a ground, a camera configured to photograph the lighting irradiated to the ground to obtain information on a form of the lighting of the lamp, and a controller configured to determine at least one of the form of the ground to which the lighting is irradiated and whether or not an obstacle exists on the ground to which the lighting is irradiated, based on the information on the obtained form of the lighting of the lamp.

A BSM unit according to an embodiment is attached to a side surface facing the vehicle body of a visor of an outer mirror provided to a vehicle body of a vehicle. The BSM unit includes a light source; a housing configured to accommodate the light source; and a lens configured to be attached to the housing and emit light from the light source to the outside of the housing, in which at least a portion of the lens protrudes from the side surface of the visor in an out-of-plane direction of the side surface.

A vehicle rearview warning system has a rearview-mirror monitor, a front image-capturing device outputting a front driving image, a rear image-capturing device outputting a rear driving image, and an edge computing device signally connected to the rearview-mirror monitor, the front image-capturing device, and the rear image-capturing device. The edge computing device receives the front driving image and the rear driving image respectively, recognizes a vehicle object from the front driving image or the rear driving image, and determines whether to activate the rearview-mirror monitor to display a warning image according to the vehicle object.

Electric vehicles may have alternative positions for the drivetrain components such as the electric motor such as toward the rear of the vehicle. Thus, the hood/bonnet of the vehicle may be shortened and various features of the vehicle may be adjusted. For example, the driver may be seated at a position more towards the front of the vehicle. Various features of the vehicle may be adjusted to accommodate the driver's altered positioning. For example, the electric vehicle may include forward positioned side view minors that are disposed on an angled mounting arm such that the field of view of the mirrors meets regulatory requirements for vehicles. Additional embodiments incorporate a street view window disposed at the front portion of the vehicle and designed to allow increased forward visibility for the driver.

The vehicular blind spot warning system is a safety device. The vehicular blind spot warning system comprises a master alarm circuit, a plurality of sensor circuits, a plurality of remote alarm circuits, a personal data device, and a vehicle. The master alarm circuit mounts in the vehicle. The plurality of sensor circuits and the plurality of remote alarm circuits mount on the exterior surface of the vehicle. The personal data device forms a communication link with the master alarm circuit. The vehicular blind spot warning system monitors a 360 degree field of view around the vehicle. The vehicular blind spot warning system generates a plurality of audible and visible alarms when: a) the vehicular blind spot warning system detects traffic that is near to the vehicle; and, b) the vehicular blind spot warning system detects traffic that is moving in a dangerous direction relative to the vehicle.

Automatic drive mode lighting systems and methods are disclosed herein. An example method can include determining when a drive mode of a vehicle is an off-road mode, determining when a speed of the vehicle is below a speed threshold, determining when a location of the vehicle corresponds to an off-road location, and automatically activating off-road lighting for the vehicle when the drive mode is in an off-road mode, the speed is below the speed threshold, and the location corresponds to an off-road location.

A turn signal lamp for an outside mirror is disclosed. The turn signal lamp comprises a lens and a light source module coupled to one side of the lens. The light source module includes a printed circuit board (PCB), a PCB assembly including a light emitting diode (LED) disposed on the PCB to output light, and a light source module case configured to accommodate the PCB assembly in an internal space. The light source module case includes a recess formed horizontally along a circumference of a surface of the light source module case. The lens includes a lens protrusion in which a part of the lens protrudes in a shape corresponding to the recess. The lens protrusion is inserted into the recess to come into close contact with a front surface of the recess, so that the light source module and the lens are coupled to each other.

An interior rearview mirror assembly for a vehicle includes a mirror head, a mirror mounting structure configured to adjustably mount the mirror head at an interior portion of the vehicle, and a receiving portion for receiving a portable accessory module. A retaining element is configured to attach at the mirror casing at the receiving portion to releasably secure the portable accessory module at the receiving portion. With the retaining element at least partially detached from the mirror casing, the portable accessory module is insertable into and removable from the receiving portion. With the portable accessory module inserted into and received at the receiving portion and with the retaining element attached at the mirror casing, the retaining element overlaps a lower portion of the portable accessory module to secure the portable accessory module at the receiving portion.

An exterior mirror for a vehicle, a retaining system for use with a functional component of a vehicle and a vehicle comprising at least one such exterior mirror. It is provided that an exterior mirror for a vehicle comprises a retaining system having a mirror module arranged thereon and at least one functional module having at least one illuminant. In an interior region of the exterior mirror, at least two retaining elements, each having groove regions, are arranged on the retaining system such that the at least one functional module is reversibly arrangeable, via sliding elements arranged on the functional module between the respective groove regions in at least one user-defined position in the interior region of the exterior mirror. In addition, a retaining system and a vehicle comprising at least one such exterior mirror are provided.