A mounting device for selectively positioning an optical element within a field-of-view of an optical sensor of a vehicle includes: a housing defining an opening sized to fit over an aperture of the optical sensor; a holder for the optical element connected to the housing and positioned such that, when the holder is in a first position, the optical element is at least partially within the field-of-view of the optical sensor; and a motorized actuator. The motorized actuator can be configured to move the holder to adjust the position of the optical element relative to the field-of-view of the optical sensor.

A roof mounted vehicle camera assembly includes a disk that can be positioned on a roof of a vehicle. A magnet is coupled to the disk to magnetically engage the roof of the vehicle for retaining the disk on the roof of the vehicle. A rod is coupled to and extends upwardly from the disk and an orb is coupled to the rod such that the orb is elevated above the roof of the vehicle when the disk is positioned on the roof of the vehicle. A pair of proximity sensors is each of the proximity sensors is integrated into the orb and a camera is integrated into the orb. A transmitter is integrated into the disk and the transmitter is in wireless communication with an extrinsic electronic device to facilitate imagery captured by the camera to be viewed on the extrinsic electronic device thereby facilitating a driver of the vehicle to view the imagery.

A surveillance equipment platform mounting in an interior cabin of a vehicle. The interior cabin of the vehicle has a roof with an opening. The surveillance equipment platform includes a retractable telescoping structure having surveillance equipment mounted so as to extend through the opening of the roof, and to fully retract into the interior cabin. The surveillance equipment platform also includes a sealing device that mounts to the retractable telescoping structure below the surveillance equipment and oriented parallel to the roof of the interior cabin. The sealing device includes an elastically deformable gasket that elastically deforms during travel of the sealing device through the roof of the interior cabin when the surveillance equipment extends through the opening in the roof during extension of the retractable telescoping structure, and when the surveillance equipment retracts into the interior cabin during retraction of the retractable telescoping structure.

Provided is a storage system for a pickup truck cargo bed. The storage system includes a frame assembly dimensioned to be nested within and fixedly attached to the cargo bed between opposing side wall sections thereof, the frame assembly further being dimensioned to extend the length of the cargo bed. The storage system additionally includes a first drawer configured to be deployable from the frame assembly, and a second drawer configured to be deployable from the frame assembly, the first and second drawers being separately deployable. The frame assembly further includes a load supporting top wall to permit for the transport of goods in the area above the storage system.

To appropriately transmit far-infrared rays while ensuring design. A far-infrared ray transmission member (20) includes a base material (30) configured to transmit far-infrared rays, and a functional film (31) formed on the base material (30). Dispersion of reflectances with respect to pieces of light at a wavelength of 360 nm to 830 nm in increments of 1 nm is equal to or smaller than 30, a reflectance with respect to visible light defined by JIS R3106 is equal to or lower than 25%, and an average transmittance with respect to light at a wavelength of 8 μm to 12 μm is equal to or higher than 50%.

A vehicle control system includes a camera configured to capture image data depicting a field of view proximate the vehicle is disclosed. The vehicle control system further includes a plurality of light sources in connection with the vehicle and a controller. The controller is configured to activate a plurality of lights in an alternating pattern and capture light reflected from at least one object with the camera at a time and corresponding to the alternating pattern of the plurality of lights. In response to variations in the light impinging upon the at least one object from the alternating pattern, the controller is configured to identify a distance of the object.

A sensor enclosure comprises a cover and a structure. The structure can be encased by the cover. The structure comprises a frame, a ring, and one or more anchoring posts. The frame can be configured to mount one or more sensors. The ring, disposed peripherally to the frame, can be operatively coupled to the cover. The ring can include a drainage ring plate that drains rainwater accumulated on the cover away from the sensor enclosure. The one or more anchoring posts, disposed underneath the frame and the ring, can be used to anchor the sensor enclosure to a vehicle.

A driver assistance apparatus includes an external camera disposed at a vehicle so as to have an outer field of view of the vehicle, configured to obtain image data on the outer field of view of the vehicle; an internal camera disposed inside the vehicle to grasp a drivers gaze on board the vehicle, configured to obtain the drivers gaze data; and a controller including at least one processor configured to process the image data and the gaze data. The controller may be configured to grasp the driver's gaze based on the gaze data, and based on a determination that the driver is in a careless condition, to control at least one of a control timing of a steering device and a lateral distance limit value for operating the steering device to be changed.

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 towing assist device includes an imaging device configured to capture a rear area from a towed vehicle when a towing vehicle moves backward, the towed vehicle being connected to the towing vehicle via a connector; a monitor device including a display screen configured to display a captured image which is captured by the imaging device, a touch screen function for detecting a touch position to the display screen; and a controller that is connected to the imaging device and the monitor device and is configured to control a display of the monitor device when the towing vehicle moves backward. The controller includes a display setting processing portion, a model display processing portion, a touch operation detection portion, and a movement direction model display processing portion.