Abstract: A method, a system and a computer-readable medium for reconstructing a vehicle moving path are provided. In the method, a plurality of vehicle recognition results of a plurality of first monitoring frames captured by a plurality of first type road monitors are received and compared to find at least one similar vehicle. Next, according to a disposition location of each first road monitor and the comparison result of each vehicle, at least one passing spot and a driving time that each vehicle moves between the disposition locations are estimated. Then, tracking data of at least one moving object appeared in multiple second monitoring frames captured by multiple second type road monitors disposed in the passing spots is inquired. Finally, the vehicles are compared with the tracked moving objects to find the moving object associated with each vehicle, so as to construct a complete moving path of each vehicle.

Abstract: Enabled is to estimate a self-position even when no landmark is seen or when an article confusing the landmark is brought in. An omnidirectional camera recognizes a vertical land-mark near a wall to determine a candidate for the self-position. On the basis of the candidate determined, a break in a map between a floor and a wall is projected on the camera image thereby to perform the matching.

Abstract: A computer implemented method of operating a navigation system to provide road curvature is provided. The method comprises obtaining a plurality of spline control points representing a two-dimensional geometry of a portion a road segment and obtaining data indicating a road grade of the portion of the road segment. The spline control points and data indicating road grade are obtained from a geographic database associated with the navigation system. The method further comprises projecting the spline control points onto a slope provided by the road grade to obtain a representation of a restored true road curvature of the portion of the road segment.

Abstract: A movable-body navigation information display unit is provided. In the movable-body navigation information display unit, a driver can intuitively and accurately recognize a relation between navigation information and a real picture or a real landscape. In addition, it is possible to avoid a state that visibility of a caution-needed picture such as a pedestrian in the real picture and a real picture of a road construction site is inhibited by an image of the navigation information. An image data creating section (405) matches road shape data with a road shape model to estimate posture data. In addition, the image data creating section creates picture (image) data for accurately compositing and displaying the image of the navigation information in an appropriate position in a real picture (or in a real landscape) of a road ahead of a movable body, and displays the navigation information as a three-dimensional icon or the like. A picture display section (5) performs display based on the picture data.

Abstract: An operating system is provided for controlling an unmanned vehicle. The system includes a stratified plurality of instruction layers, a behavior axiom block and a set of operation parameters. The instruction layers are substantially arranged in descending priority order. Each layer provides an information signal to either an adjacent descending layer or an operation device on board the unmanned vehicle. The behavior axiom block provides an independent protocol signal to a first instruction layer in said stratified plurality. The operation parameters provide an environmental condition that neighbors the unmanned vehicle to a second instruction layer. Preferably, the behavior axiom block includes prioritization adjustment to an instruction layer for overriding the information signal from an adjacently ascendant layer, such as by an interrupt signal.

Abstract: Systems, methods, and computer program products for flight validation (FV) are provided. Embodiments implement the requirements of FAA Notice 8260.67 as they relate to FV. Embodiments enable FV to be performed in its entirety, including flight and/or ground obstacle assessment, and on-course/on-path flight evaluation. Embodiments enable a post-flight validation phase, which provides post flight analysis and archiving capabilities. Using embodiments, a person of minimal skill and training can perform FV as prescribed by FAA requirements. Accordingly, significant costs associated with hiring professional surveyors and air crews to perform obstacle assessment and flight evaluation can be eliminated. Embodiments can be implemented using commercial off-the-shelf (COTS) and relatively inexpensive hardware, making them suitable for large-scale FV operations.