A method for delineating parking stalls on a parking lot surface includes providing lengths of webbing and a plurality of stake assemblies. The method proceeds by arranging the lengths of webbing in a desired pattern on the parking lot surface that delineates parking stalls, preferably stretching them lengthwise, and then driving stake assemblies through holes in the webbing and into the underlying body of material in order to secure the webbing on the parking lot surface. A parking lot installation constructed according to the invention includes a plurality of lengths of webbing that have been arranged and secured as stated above. The method is not limited to parking lots and parking stall delineation, as it can be used to mark a boundary or delineate a space for other purposes.

An apparatus for locating an object of interest using offset. The object may be a mobile platform, or portion of same, associated with a vehicle, or a pavement segment or feature of or on a pavement segment on which the mobile platform is located. The vehicle includes first and second fixed points having a known offset from each other. An image sensor whose field of view includes the second fixed point and a segment of the pavement surface provides image data which is used with the known offset to calculate the precise location of the object of interest.

A ground tape applicator is configured to apply adhesive tape to ground surfacers. The ground tape applicator includes a plurality of rollers that guide the adhesive tape to the ground surface and apply the adhesive tape to the ground surface. The ground tape applicator includes a blade configured to engage with the adhesive tape to cut the adhesive tape to a desired length.

Installation cart for laying a magnetic marker in a road to achieve driving assist control on a vehicle side has boring drill at each of front and rear of vehicle body, the boring drill boring accommodation hole as a laying position for the magnetic marker in road surface, is capable of boring accommodation holes at two locations with a predetermined space without moving in a state of being parked at any position, and is capable of performing efficient laying operation without requiring, for example, positioning of installation cart for enhancing accuracy of a space between these accommodation holes at two locations forming the laying positions.

Installation cart for laying a magnetic marker in a road to achieve driving assist control on a vehicle side has boring drill at each of front and rear of vehicle body, the boring drill boring accommodation hole as a laying position for the magnetic marker in road surface, is capable of boring accommodation holes at two locations with a predetermined space without moving in a state of being parked at any position, and is capable of performing efficient laying operation without requiring, for example, positioning of installation cart for enhancing accuracy of a space between these accommodation holes at two locations forming the laying positions.

A road marker placement system has a frame, a holder mechanically coupled to the frame, a drive system mechanically coupled to the frame, and a rotatable carrier mechanically coupled to the drive system to allow the rotatable carrier to be rotationally driven by the drive system. The rotatable carrier has at least a first pocket formed therein that receives one of the road markers dispensed from an opening of the holder when the rotatable carrier is in a first position. The rotatable carrier is rotated by the drive system from the first position to a second position that is facing the road surface such that the road marker held in the first pocket is forced at least by gravity and by centrifugal force of the rotating rotatable carrier to be ejected from the first pocket onto an adhesive material located on the road surface.

A road marker placement system has a frame, a holder mechanically coupled to the frame, a drive system mechanically coupled to the frame, and a rotatable carrier mechanically coupled to the drive system to allow the rotatable carrier to be rotationally driven by the drive system. The rotatable carrier has at least a first pocket formed therein that receives one of the road markers dispensed from an opening of the holder when the rotatable carrier is in a first position. The rotatable carrier is rotated by the drive system from the first position to a second position that is facing the road surface such that the road marker held in the first pocket is forced at least by gravity and by centrifugal force of the rotating rotatable carrier to be ejected from the first pocket onto an adhesive material located on the road surface.

A system for providing smart road infrastructure for the purpose of vehicle safety and autonomous driving, comprising a plurality of road units, which are located along the borders of each traffic lane and equally spaced from each other, where each road unit includes a read/write passive RF tag; antenna for communicating with a plurality of transceivers, each of which is installed on each vehicle that travels along a traffic lane of said road, in response to signals transmitted from said transceivers; a memory for temporarily storing data regarding each vehicle traveling along said lane. Each car unit comprises a reader for interrogating said tags. The reader includes a first transceiver that is installed on the left front of said vehicle and a second transceiver that is installed on the right front of said vehicle; a processor being in bidirectional data communication with said transceivers and with the vehicle inherent control systems, for processing data received from said tags and calculating speed and location of said vehicle with respect to the borders of said lane and to other neighboring vehicles traveling in said lane and adjacent lanes, to implement vehicle safety operations such as Lane Departure Warning, Forward Collision Warning, Lane Keeping Assist, Lane Centering, Side Collision Warning. Alerting the driver (visually and/or audibly) regarding potential problems and/or taking over control of the vehicle (ADAS 1-5). The system can provide Connected Vehicles with accurate (ubiquitous and instantaneous) location data with lane-level resolution. The proposed smart infrastructure may complement car sensors and/or connected vehicles, so as to implement a combination that yield the most relabel and cost-effective autonomous driving system.

An apparatus 10 and method is disclosed for creating one or more notes as a car 14 drives over the apparatus 10 on a road surface 12. The apparatus 10 can include a first strip 16 of durable material having a length 58 and a width 52; and a first plurality of recesses 20 defined in the first strip 16, each of the first plurality of recesses 20 extending across a portion of the width 52 of the first strip 16; wherein the first plurality of recesses 20 are spaced along the length 58 of the first strip 16 a first distance 24 from one another, the first plurality of recesses 20 producing a first note when the first strip 16 is placed on the road surface 12 and the car 14 drives over the length 58 of the first strip 16.

An installation system has a laser range finder set at a reference position to measure a distance to a target, an installation cart which performs operation for laying a magnetic marker in a road, and an arithmetic unit which identifies a position relation of a laying position where the magnetic marker is laid with respect to the reference position. When operation for laying the magnetic marker in a road is performed, by taking the installation cart during performing the operation of laying the magnetic marker in the road as a target, based on a distance to the installation cart measured by the laser range finder, the position relation of the laying position with respect to the reference position is identified by the arithmetic unit.