A modular intelligent transportation system, comprising an environmentally protected enclosure, a system communications bus, a processor module, communicating with said bus, having a image data input and an audio input, the processor module analyzing the image data and/or audio input for data patterns represented therein, having at least one available option slot, a power supply, and a communication link for external communications, in which at least one available option slot can be occupied by a wireless local area network access point, having a communications path between said communications link and said wireless access point, or other modular components.

A modular intelligent transportation system, comprising an environmentally protected enclosure, a system communications bus, a processor module, communicating with said bus, having a image data input and an audio input, the processor module analyzing the image data and/or audio input for data patterns represented therein, having at least one available option slot, a power supply, and a communication link for external communications, in which at least one available option slot can be occupied by a wireless local area network access point, having a communications path between said communications link and said wireless access point, or other modular components.

A backup camera system integrates various capabilities in a common housing to deliver enhanced safety and convenience functions for less cost and improved utility. Apparatus such as an inertial measurement unit (IMU) may be used to automatically detect when the vehicle is moving in reverse, such that no signal is required from the vehicle to determine that the vehicle is moving in reverse. The IMU may further detect a crash situation. A sound or light generator may provide an alert to an area surrounding the vehicle. Integrated communications capabilities provide for remote control of various functions and the exchange of signals and information to remote devices facilitating vehicle-to-vehicle, vehicle-to-infrastructure or infrastructure-to-vehicle communications. The system may further integrate proximity detection, imaging and computer-readable code interpretation, and GPS location.

A backup camera system integrates various capabilities in a common housing to deliver enhanced safety and convenience functions for less cost and improved utility. Apparatus such as an inertial measurement unit (IMU) may be used to automatically detect when the vehicle is moving in reverse, such that no signal is required from the vehicle to determine that the vehicle is moving in reverse. The IMU may further detect a crash situation. A sound or light generator may provide an alert to an area surrounding the vehicle. Integrated communications capabilities provide for remote control of various functions and the exchange of signals and information to remote devices facilitating vehicle-to-vehicle, vehicle-to-infrastructure or infrastructure-to-vehicle communications. The system may further integrate proximity detection, imaging and computer-readable code interpretation, and GPS location.

The present invention relates to a camera module, comprising: a lens barrel including a body part, and an extension part extending outwardly from the body part; a front body including a through hole into which the body part is inserted, and a placing part on the top of which the extension part is disposed; and an adhesive disposed between the extension part and the placing part, wherein a concave-convex part may be formed on the placing part. The present invention has an effect of enhancing adhesive force between the lens barrel and the front body, thereby maintaining airtightness of an inner space and improving reliability and stability.

The present invention relates to a camera module, comprising: a lens barrel including a body part, and an extension part extending outwardly from the body part; a front body including a through hole into which the body part is inserted, and a placing part on the top of which the extension part is disposed; and an adhesive disposed between the extension part and the placing part, wherein a concave-convex part may be formed on the placing part. The present invention has an effect of enhancing adhesive force between the lens barrel and the front body, thereby maintaining airtightness of an inner space and improving reliability and stability.

A method is provided for producing an assembled cross car beam. That method includes the steps of assembling component parts together to produce an assembled cross car beam, scanning and measuring, by a scanning device the assembled cross car beam and creating component locators in correct positions on the assembled cross car beam for the subsequent installation of component parts such as AHU and instrument panel components.

The present invention relates to a camera module, comprising: a lens barrel including a body part, and an extension part extending outwardly from the body part; a front body including a through hole into which the body part is inserted, and a placing part on the top of which the extension part is disposed; and an adhesive disposed between the extension part and the placing part, wherein a concave-convex part may be formed on the placing part. The present invention has an effect of enhancing adhesive force between the lens barrel and the front body, thereby maintaining airtightness of an inner space and improving reliability and stability.

The present invention relates to a camera module, comprising: a lens barrel including a body part, and an extension part extending outwardly from the body part; a front body including a through hole into which the body part is inserted, and a placing part on the top of which the extension part is disposed; and an adhesive disposed between the extension part and the placing part, wherein a concave-convex part may be formed on the placing part. The present invention has an effect of enhancing adhesive force between the lens barrel and the front body, thereby maintaining airtightness of an inner space and improving reliability and stability.

An onboard device includes a body member, a support member projecting from the body member and including a base to be attached to a concave inner surface of a glass member having a curved shape provided in a vehicle, and a double-sided adhesive tape stuck on a the base. The base is a plate-like member including an attachment surface to be opposed to the inner surface of the glass member. The attachment surface is a curved surface having a curvature at least in a first direction along the attachment surface. The double-sided adhesive tape is provided with at least one first slit open toward an upper edge located on the upper side and cut downward and at least one second slit open toward a lower edge located on the lower side and cut upward when the base (3) is attached to the inner surface.