A roll display sign device for displaying an information sheet for a vehicle includes a housing, which defines an interior space. The housing is selectively engageable to a window of a vehicle so that the housing is removably engaged to the window. A slot is positioned in the housing. A panel, which is wound and which is positioned in the interior space, is reversibly extensible through the slot so that the panel is viewable through the window of the vehicle. The panel has indicia positioned thereon, can selectively engage indicia, or can selectively engage a sheet upon which indicia are positioned. The indicia are capable of being read by a person who is positioned proximate to the window.

A windshield the invention is a windshield on which an information acquisition device that emits and/or receives light to acquire information from an outside of a vehicle can be arranged, and the windshield includes a glass sheet in which at least a portion is curved and on which a mask layer that blocks a field of vision from the outside of the vehicle is laminated, at least one opening being formed in the mask layer, an attachment member in which at least a portion is fixed at a position corresponding to the mask layer on the glass sheet and to which the information acquisition device can be attached, and a path member having a recessed portion for forming a path through which the information acquisition device emits and/or receives light between the path member and the glass sheet when the attachment member is fixed to the mask layer.

A camera module, which is mounted on an inside of a front windshield of a vehicle and to image an external environment of the vehicle, includes a lens unit and an imager to image the external environment by forming an optical image, which is from the external environment through the lens unit.

A camera module is attached to an inside of a windshield of a vehicle to capture an image of an outside view. The camera module includes an imager, a lens set equipped with a first lens and a second lens, a lens barrel in which the lens set is disposed, and a main spacer fit in the lens barrel. The lens barrel retains the first lens using an axial force oriented along an optical axis of the lens set. The main spacer is disposed between the first and second lenses and transmits the axial force from one of the first and second lenses to the other. This structure enables the camera module to be reduced in size without sacrificing the optical performance thereof.

An approach is provided for determining an optimal alignment of a device. The approach, for example, involves receiving image data from a device mounted in a vehicle. The approach also involves presenting an alignment template in a user interface of the device as an overlay on the image data, wherein the alignment template provides one or more guidelines indicating a target alignment of the device to capture images from the vehicle for an application. The approach further involves processing the image data against the alignment template to determining an alignment of the device in relation to the target alignment.

An articulated stand including a first part and a second part. The first part is configured for holding an electronic device. The first part includes a ball pivot with a chamber and a connector. The chamber defined through the ball pivot. The connector accommodated at least partially in the chamber. The connector configured to electrically connect with a cable connector. The second part including a ball housing portion receiving the ball pivot to form a ball joint.

A vehicular heads-up-display system includes an apparatus having a base configured to receive and maintain a pico-projector case in combination with a handheld electronic device, and to output optical transmissions from the pico-projector case to an at least partially reflective surface to form a heads-up display. The partially reflective surface may be a combiner and/or mirror coupled to a base comprising the holder. The handheld electronic device may be a smartphone. For example, the system can be used to cause a pico-projector to project information from a smartphone to a partially reflective mirror for viewing by a vehicle operator.

A forward facing imaging system for a vehicle includes an interior rearview mirror assembly mounted at an interior portion of a vehicle and a camera disposed at the interior rearview mirror assembly. The camera has a forward field of view through a windshield of the vehicle. The camera captures image data and captured image data is recorded by a recording system. During operation of the vehicle, the recording system records image data, as it is captured over a given period of operation of the vehicle, in a closed-loop fashion onto electronic memory. Image data, as captured by the camera, is processed by an image processor in order to determine the presence of at least one object forward of the equipped vehicle.

A camera module, in particular for a vehicle, the camera module having at least: an objective having a lens mount and at least one lens, an image sensor for acquiring and converting optical signals into electrical signals, a bearer device on which the image sensor is mounted and contacted, and a camera housing for accommodating the objective and the bearer device. The objective is connected to the camera housing, in particular to a first housing part, and is borne by the camera housing. The bearer device can in particular be fixed on the objective or on the first housing part.

A vehicular driver monitoring system includes an interior electrochromic rearview mirror assembly and a camera disposed at the interior electrochromic rearview mirror assembly behind and viewing through an electrochromic mirror reflective element into the interior cabin of the vehicle. Supplemental sources of near infrared illumination are integrated into the mirror assembly that, when powered to emit near infrared light, illuminate at least the driver-side front seating area within the interior cabin of the vehicle. Presence of the camera is not readily apparent to an occupant of the vehicle. The camera at least (a) views the driver-side front seating area of the equipped vehicle and (b) views a passenger-side front seating area of the equipped vehicle. The driver of the equipped vehicle is monitored via processing at the processor of image data captured by the camera.