An integrated auto-level and electronic rod reader is disclosed. In one embodiment, the integrated auto-level and electronic rod reader comprises a telescope and an image delivery device integrated with the auto-level which is configured for capturing an image of a standard grade rod visible through the telescope and a crosshair. Logic implemented by a processor automatically recognizes the crosshair, automatically compares the crosshair against a scale of the standard grade rod, and automatically determines an elevation of the standard grade rod based upon the comparing.

Aspects of the disclosure provide for the generation of a driving difficulty heat map for autonomous vehicles. For instance, log data generated by a vehicle being driven in a manual driving mode for a segment of a route may be input into a disengage model in order to generate an output identifying a likelihood of a vehicle driving in an autonomous driving mode requiring a disengage from the autonomous driving mode along the segment of the route. The log data may have been collected within a geographic area. A grid for the geographic area may be generated. The grid may include a plurality of cells. The output is assigned to one of the plurality of cells. The plurality of cells and assigned output may be used to generate a driving difficulty heat map for the geographic area.

A system and methods are provided for generating photogrammetry data acquisition plans of target structures, including: establishing a location and orientation of the target structure; identifying on the target structure predetermined target objects designated for data acquisition; correlating shapes, locations, and orientations of the target objects with the shape, location, and orientation of the target structure; and applying the shapes, locations, and orientations of the target structure and of the target objects, to generate a data acquisition plan for drone photogrammetry of the target structure and of the target objects.

A system and methods are provided for generating photogrammetry data acquisition plans of target structures, including: establishing a location and orientation of the target structure; identifying on the target structure predetermined target objects designated for data acquisition; correlating shapes, locations, and orientations of the target objects with the shape, location, and orientation of the target structure; and applying the shapes, locations, and orientations of the target structure and of the target objects, to generate a data acquisition plan for drone photogrammetry of the target structure and of the target objects.

An integrated auto-level and electronic rod reader is disclosed. In one embodiment, the integrated auto-level and electronic rod reader comprises a telescope and an image delivery device integrated with the auto-level which is configured for capturing an image of a standard grade rod visible through the telescope and a crosshair. Logic implemented by a processor automatically recognizes the crosshair, automatically compares the crosshair against a scale of the standard grade rod, and automatically determines an elevation of the standard grade rod based upon the comparing.

An integrated auto-level and electronic rod reader is disclosed. In one embodiment, the integrated auto-level and electronic rod reader comprises a telescope and an image delivery device integrated with the auto-level which is configured for capturing an image of a standard grade rod visible through the telescope and a crosshair. Logic implemented by a processor automatically recognizes the crosshair, automatically compares the crosshair against a scale of the standard grade rod, and automatically determines an elevation of the standard grade rod based upon the comparing.

An integrated auto-level and electronic rod reader is disclosed. In one embodiment, the integrated auto-level and electronic rod reader comprises a telescope and an image delivery device integrated with the auto-level which is configured for capturing an image of a standard grade rod visible through the telescope and a crosshair. Logic implemented by a processor automatically recognizes the crosshair, automatically compares the crosshair against a scale of the standard grade rod, and automatically determines an elevation of the standard grade rod based upon the comparing.

An integrated auto-level and electronic rod reader is disclosed. In one embodiment, the integrated auto-level and electronic rod reader comprises a telescope and an image delivery device integrated with the auto-level which is configured for capturing an image of a standard grade rod visible through the telescope and a crosshair. Logic implemented by a processor automatically recognizes the crosshair, automatically compares the crosshair against a scale of the standard grade rod, and automatically determines an elevation of the standard grade rod based upon the comparing.

The present disclosure refers to a measurement and stabilization module couplable to drones and portable stabilizers for linear measurement and identification of inclination of structures. This module comprises: a telemetric housing, subdivided into: a front portion, a lower portion, a rear portion, a right side portion and a left side portion; a protective cage; rods of a gimbal; four engagement elements and four engagement rotation elements.

The present disclosure refers to a measurement and stabilization module couplable to drones and portable stabilizers for linear measurement and identification of inclination of structures. This module comprises: a telemetric housing, subdivided into: a front portion, a lower portion, a rear portion, a right side portion and a left side portion; a protective cage; rods of a gimbal; four engagement elements and four engagement rotation elements.