Abstract: A navigation system and method for an autonomous vehicle (AV) that includes a system controller and an environmental sensor. The system controller determines a fixed local frame (LCF) having a coordinate system originating at a fixed location in three-dimensional space. Additionally, the system controller determines an AV positional pose in LCF coordinates, which identifies an AV position in three-dimensional space and an AV orientation in three-dimensional space. An environmental sensor detects an asset feature of an asset moving within three-dimensional space. The system controller then identifies an asset feature frame (AFF) having a coordinate system originating at the asset feature. A localization module determines the AV positional pose in the AFF coordinates. The system controller then dynamically transforms the AV position pose from the LCF coordinates to the AFF coordinates and generates a motion control command based on the AV positional pose in the AFF coordinates.

Abstract: Systems and methods for determining an Automated Vehicle (AV) trajectory are described. More particularly, a method for determining an AV trajectory proceeds by communicatively coupling an AV content generating device to an AV system controller. The AV content generating device collects target data associated with a target. The AV system controller extracts target features from the target data. The AV system controller compares the extracted target features to target model data to determine a target pose. The AV system controller compares the target pose with at least one target objective to determine an AV trajectory.

Abstract: A navigation system and a navigation method for an autonomous vehicle (AV) includes a system controller and an environmental sensor. The system controller determines an AV positional pose, which identifies the location of the AV, which further includes an AV position and an AV orientation in three-dimensional space. Additionally, the system controller determines a frame of reference that is associated with the AV positional pose. The frame of reference includes a coordinate system for the AV position and the AV orientation. A localization module determines the AV positional pose and the corresponding frame of reference. The localization module is associated with the system controller. The system controller then identifies at least one asset feature frame (AFF), which associates the AV positional pose with the feature in the AV environment. The system controller generates a motion control command based the AV positional pose and the AFF.

Abstract: Systems and methods for collecting and geocoding object data are described. More particularly, a system for collecting and geocoding object data includes an AV, a chronicle server, and a user device. The AV receives a mission specification that includes a route to be traversed by the AV. The AV traverses the route and collects object data along the way. The AV collects location data along the route. The chronicle server receives the object data and the location data from the content generating device. The object data and the location data are associated with a geocoded object (GLOB). The chronicle server generates a GLOB chronicle from a plurality of GLOBs, in which a time is associated with each of the GLOBs and a location is associated with each of the GLOBs. A user device displays the GLOB.