Context-based navigation of uncrewed vehicles using relative position markers

What is claimed is: 1. An uncrewed aerial vehicle (UAV), comprising: an imaging system; and a control system configured to: cause the UAV to fly to a coarse-navigation location at a locale of a cluster of charging pads, the cluster comprising the charging pads arranged in a layout, and a plurality of fiducial markers distributed at positions across the layout; cause the imaging system to acquire an image of one or more charging pads of the cluster and an observed sub-plurality of the fiducial markers in a vicinity of the one or more charging pads, wherein the acquired image represents an observed constellation of fiducial markers at apparent positions and orientations relative to the one or more charging pads, as viewed from a position and orientation of the UAV at the coarse-navigation location; in a reference map of the layout and a reference sub-plurality of the fiducial markers, identify at least a portion of a reference constellation of fiducial markers at reference positions and orientations relative to one or more reference charging pads in the reference map, wherein the reference map associates each respective charging pad of the charging pads of the cluster with a corresponding reference constellation of fiducial markers, and wherein a location of the respective charging pad within the cluster is represented (i) by respective positions and orientations of the fiducial markers of the corresponding reference constellation relative to the respective charging pad in the reference map and (ii) independently of respective geolocation data of the fiducial markers of the corresponding reference constellation; and based on known identities of the one or more reference charging pads and on matching the reference constellation to the observed constellation to within a degree of confidence, disambiguate an identity of a particular charging pad from among the one or more charging pads without using respective geolocation data of the reference sub-plurality of the fiducial markers. 2. The UAV of claim 1 , wherein the disambiguated identity confirms that the particular charging pad is a designated landing pad for the UAV, and wherein the control system is further configured to cause the UAV to land on the particular charging pad based on the confirmation. 3. The UAV of claim 1 , wherein the disambiguated identity confirms that the particular charging pad is not a designated landing pad for the UAV, wherein the one or more charging pads comprise two or more charging pads, and wherein the control system is further configured to: based on the known identities of the one or more reference charging pads and on matching the reference constellation to the observed constellation to within the degree of confidence, identify a different charging pad of the two or more charging pads as the designated landing pad for the UAV; and cause the UAV to land on the different charging pad based on its identity as the designated landing pad. 4. The UAV of claim 1 , further comprising a memory storing the reference map. 5. The UAV of claim 1 , wherein the layout is a grid, and wherein the plurality of fiducial markers are distributed in regular positions across the grid. 6. The UAV of claim 1 , wherein the fiducial markers are identifiable by physical features that do not uniquely distinguish every fiducial marker from among the plurality, and wherein at least one fiducial marker of the plurality has a physical feature that enables detection of an angular orientation of the at least one fiducial marker. 7. The UAV of claim 1 , wherein causing the UAV to fly to the coarse-navigation location comprises using a coarse-navigation mode of a navigation system of the UAV to fly the UAV, with a given likelihood of navigational success, to an arrival position that is within a coarse tolerance of a target position directly above a designated target charging pad, and wherein disambiguating the identity of the particular charging pad from among the one or more charging pads comprises determining whether or not the particular charging pad is the designated target charging pad. 8. The UAV of claim 1 , wherein matching the reference constellation to the observed constellation to within the degree of confidence comprises applying a pattern matching operation to the observed constellation and the reference constellation. 9. The UAV of claim 8 , wherein the pattern matching operation is implemented by a geometric transformation computation. 10. The UAV of claim 8 , wherein the pattern matching operation is implemented by a machine-learning pattern recognition program. 11. The UAV of claim 1 , wherein the control system is further configured to cause the UAV to send data comprising an aerial image of the cluster of the charging pads to a server in an infrastructure support network for UAVs, wherein the server is configured to use the aerial image for updating a network copy of the reference map, and wherein the network copy is provided by the server to UAVs having missions that include flying to the cluster of the charging pads. 12. The UAV of claim 1 , wherein the layout is a grid, and wherein the plurality of fiducial markers are distributed in random positions across the grid. 13. The UAV of claim 1 , wherein two or more fiducial markers of the plurality of fiducial markers are non-unique within the plurality of fiducial markers. 14. A method carried out by an uncrewed aerial vehicle (UAV), the method comprising: receiving a reference map of a cluster of charging pads from a server in an infrastructure support network for UAVs, wherein the cluster comprises the charging pads arranged in a layout and a plurality of fiducial markers distributed at positions across the layout, wherein the reference map represents the layout and a reference sub-plurality of the fiducial markers, wherein the reference map associates each respective charging pad of the charging pads of the cluster with a corresponding reference constellation of fiducial markers, and wherein a location of the respective charging pad within the cluster is represented (i) by respective positions and orientations of the fiducial markers of the corresponding reference constellation relative to the respective charging pad in the reference map and (ii) independently of respective geolocation data of the fiducial markers of the corresponding reference constellation; storing the reference map in a memory of the UAV; flying to a coarse-navigation location at a locale of the cluster of the charging pads; with an imaging system of the UAV, acquiring an image of one or more charging pads of the cluster and an observed sub-plurality of the fiducial markers in a vicinity of the one or more charging pads, wherein the acquired image represents an observed constellation of fiducial markers at apparent positions and orientations relative to the one or more charging pads, as viewed from a position and orientation of the UAV at the coarse-navigation location; in the reference map, identifying at least a portion of a reference constellation of fiducial markers at reference positions and orientations relative to one or more reference charging pads in the reference map; and based on known identities of the one or more reference charging pads and on matching the reference constellation to the observed constellation to within a degree of confidence, disambiguating an identity of a particular charging pad from among the one or more charging pads without using respective geolocation data of the reference sub-plurality of the fiducial markers. 15. The method of claim 14 , wherein disambiguating the identity comprises confirmin