Flight planning for unmanned aerial tower inspection with long baseline positioning
First Claim
1. A method to plan a flight to inspect a tower with an un-manned aerial vehicle comprisingdefining a reference base station,receiving location correction messages from a plurality of continuously operating reference stations more than two tower heights away from said tower,incorporating said correction messages in a location rover mounted on said unmanned aerial vehicle,scanning said tower in three dimensions to create a three dimensional model of said tower relative to said reference base station,determining a standoff distance using wind speed and stability of said unmanned aerial vehicle for said flight,generating a plurality of flight segments from said model maintaining said standoff distance, positioned relative to said reference base station to inspect said tower.
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Abstract
Inspections of towers with unmanned aerial vehicles is challenging because judging the distance to narrow tower members, phase conductors, or guy wires is very difficult for people. These flights may be automated by first creating a three dimensional model of the tower from a scan; determining a safe standoff distance for the unmanned aerial vehicle; generating flight segments to provide complete inspection coverage of the tower while maintaining the standoff distance; and then safely and accurately flying the segments in most wind conditions by using location correction messages from remote reference stations.
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Citations
16 Claims
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1. A method to plan a flight to inspect a tower with an un-manned aerial vehicle comprising
defining a reference base station, receiving location correction messages from a plurality of continuously operating reference stations more than two tower heights away from said tower, incorporating said correction messages in a location rover mounted on said unmanned aerial vehicle, scanning said tower in three dimensions to create a three dimensional model of said tower relative to said reference base station, determining a standoff distance using wind speed and stability of said unmanned aerial vehicle for said flight, generating a plurality of flight segments from said model maintaining said standoff distance, positioned relative to said reference base station to inspect said tower.
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5. A flight planning system for the inspection of a tower using an unmanned aerial vehicle comprising
a location rover mounted on said unmanned aerial vehicle to receive correction messages from a reference base station, a non-contact three-dimensional scanner to create a three dimensional model of said tower relative to said reference base station, standoff means to determine a standoff distance using wind speed and stability of said unmanned aerial vehicle for said inspection, flight segment generation means to generate a plurality of flight segments from said model for said unmanned aerial vehicle relative to said reference base station, each flight segment maintaining said standoff distance from said model.
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9. A method to inspect a tower with an unmanned aerial vehicle comprising
defining a reference base station, receiving location correction messages from a plurality of continuously operating reference stations more than two tower heights away from said tower, incorporating said correction messages in a location rover mounted on said unmanned aerial vehicle, scanning said tower in three dimensions to create a three dimensional model of said tower relative to said reference base station, determining a standoff distance using wind speed and stability of said unmanned aerial vehicle for said flight, generating a plurality of flight segments from said model maintaining said standoff distance, positioned relative to said reference base station to inspect said tower, communicating said flight segments to said unmanned aerial vehicle, providing a plurality of inspection sensors on said unmanned aerial vehicle, locating said unmanned aerial vehicle relative to said reference base station in near real-time, flying said flight segments with said unmanned aerial vehicle while gathering inspection data with said inspection sensors.
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13. A tower inspection system comprising
an unmanned aerial vehicle, a location rover mounted on said unmanned aerial vehicle to receive correction messages from a reference base station, a non-contact three-dimensional scanner to create a three dimensional model of said tower relative to said reference base station, standoff means to determine a standoff distance using wind speed and stability of said unmanned aerial vehicle for said inspection, flight segment generation means to generate a plurality of flight segments from said model for said unmanned aerial vehicle relative to said reference base station, each flight segment maintaining said standoff distance from said model, inspection sensors mounted on said unmanned aerial vehicle, locating means to determine location during flight of said unmanned aerial vehicle relative to said reference base station in near real time.
Specification