Disclosed embodiments may help an aerial vehicle network to provide substantially continuous service in a given geographic area. An example method may be carried out at an aerial vehicle that is at a location associated with the first geographic area in an aerial network that includes a plurality of
Disclosed embodiments may help an aerial vehicle network to provide substantially continuous service in a given geographic area. An example method may be carried out at an aerial vehicle that is at a location associated with the first geographic area in an aerial network that includes a plurality of geographic areas. The balloon may determine that it should update its vehicle-state in accordance with a vehicle-state profile for the first geographic area. Then, in response, the balloon may determine the vehicle-state profile for the first geographic area, which may include one or more state parameters for balloons operating in the first geographic area. The balloon may then operate according to the vehicle-state profile for the first geographic area.
대표청구항▼
1. A computer-implemented method comprising: initially, when an aerial vehicle is at a location associated with a second geographic area in an aerial network, operating the aerial vehicle according to a vehicle-state profile for the second geographic area, wherein the aerial network comprises a plur
1. A computer-implemented method comprising: initially, when an aerial vehicle is at a location associated with a second geographic area in an aerial network, operating the aerial vehicle according to a vehicle-state profile for the second geographic area, wherein the aerial network comprises a plurality of geographic areas;subsequently determining, by a computing system of the aerial vehicle, that the aerial vehicle has moved to a location associated with a first geographic area in the aerial network, and that a vehicle-state of the aerial vehicle should be updated in accordance with a vehicle-state profile for the first geographic area; andin response to determining that the vehicle-state profile should be updated: determining the vehicle-state profile for the first geographic area, wherein the vehicle-state profile comprises one or more state parameters for aerial vehicles operating in the first geographic area; andcausing the aerial vehicle to switch from operation according to the vehicle state profile for the second geographic area to operate according to the vehicle-state profile for the first geographic area, wherein the vehicle state profile for the first geographic area comprises one or more state parameters for aerial vehicles operating in the first geographic areas, and wherein the vehicle state profile for the second geographic area comprises one or more state parameters for aerial vehicles operating in the second geographic area. 2. The method of claim 1, wherein determining that the aerial vehicle should be updated with vehicle-state information for the first geographic area comprises: determining that the aerial vehicle has moved from a location that is outside of the first geographic area to a location within the first geographic area. 3. The method of claim 1, wherein determining that the aerial vehicle should be updated with vehicle-state information for the first geographic area comprises: determining that the aerial vehicle has moved from a first location that is outside of a border area of the first geographic area to a location within the border area of the first geographic area. 4. The method of claim 1, wherein determining that the vehicle-state profile should be updated comprises: determining a direction in which the aerial vehicle is travelling; anddetermining that the direction in which the aerial vehicle is travelling is towards the first geographic area. 5. The method of claim 1, wherein determining the vehicle-state profile for the first geographic area comprises: sending a profile-update request; andreceiving, as a response to the profile-update request, at least a portion of the vehicle-state profile for the first geographic area. 6. The method of claim 5, wherein sending the profile-update request comprises sending the profile-update request to one or more other aerial vehicles in the aerial network, and wherein at least a portion of the vehicle-state profile for the first geographic area is received from one or more of the other aerial vehicles. 7. The method of claim 5, wherein sending the profile-update request comprises: sending the profile-update request to a ground-based station that is associated with the first geographic area, wherein at least a portion of the vehicle-state profile for the first geographic area is received from the ground-based station. 8. The method of claim 1, wherein determining the vehicle-state profile for the first geographic area comprises: searching a communication channel for a vehicle-state signal; andreceiving the vehicle-state signal via the communication channel, wherein the vehicle-state signal indicates at least a portion of the vehicle-state profile for the first geographic area. 9. The method of claim 1, wherein the vehicle-state profile for the first geographic area indicates one or more operational parameters for aerial vehicles that are operating in the first geographic area. 10. The method of claim 9, wherein the one or more operational parameters comprise one or more of: (a) at least one parameter indicating a communication protocol or protocols to be used in the geographic area, (b) at least one parameter providing routing information for the geographic area, (c) at least one parameter relating to transmission power for aerial vehicles operating in the geographic area, (d) at least one parameter indicative of error correction coding that should be implemented by an aerial vehicle in the geographic area, (e) at least one parameter indicative of a desired topology for the aerial network in the geographic area, (f) at least one parameter that provides information related to ground-based stations or other fixed systems in the geographic area, (g) at least one parameter indicative of power management that should be implemented by an aerial vehicle in the geographic area, (h) at least one parameter affecting the horizontal and/or altitudinal movement of the aerial vehicle, and/or (i) at least one parameter providing information for complying with a legal requirement for the geographic area. 11. The method of claim 1, wherein causing the aerial vehicle to operate according to the vehicle-state profile for the first geographic area comprises updating the vehicle-state for the aerial vehicle based on the vehicle-state profile for the first geographic area. 12. The method of claim 1, further comprising: subsequently, after causing the aerial vehicle to operate according to the vehicle-state profile for the first geographic area, determining that the aerial vehicle is again at a location associated with a second geographic area of the aerial network;determining that the vehicle-state of the aerial vehicle should be updated in accordance with the vehicle-state profile for the second geographic area; andin response to determining that the vehicle-state should be updated: causing the balloon to again operate according to the vehicle-state profile for the second geographic area. 13. A computer-implemented method comprising: initially, when an aerial vehicle is at a location associated with a second geographic area in an aerial network, transmitting a second vehicle-state signal via a second communication channel, wherein the second communication channel is accessible to one or more other aerial vehicles that are operable in the aerial network, wherein the second vehicle-state signal indicates at least a portion of the vehicle-state profile for the second geographic area, and wherein the vehicle state profile for the second geographic area comprises one or more state parameters for aerial vehicles operating in the second geographic area;subsequently determining that the aerial vehicle is at a location associated with the first geographic area in the aerial network;determining a vehicle-state profile for the first geographic area, wherein the vehicle-state profile comprises one or more state parameters for aerial vehicles operating in the first geographic area; andtransmitting a first vehicle-state signal via a first communication channel, wherein the first communication channel is accessible to one or more other aerial vehicles that are operable in the aerial network, wherein the first vehicle-state signal indicates at least a portion of the vehicle-state profile for the first geographic area. 14. The method of claim 13, wherein transmitting the first vehicle-state signal comprises broadcasting the vehicle-state signal such that the vehicle-state signal is available to any aerial vehicle in the aerial network that is monitoring the first communication channel. 15. The method of claim 13, wherein the balloon is a first aerial vehicle, the method further comprising: determining, at the first aerial vehicle, that a second aerial vehicle should be updated with the vehicle-state profile for the first geographic area; andresponsively sending the first vehicle-state signal to the second aerial vehicle. 16. The method of claim 13 wherein the first communication channel is defined on an RF air-interface. 17. The method of claim 13, wherein the balloon is a first aerial vehicle, and wherein the first communication channel is defined on a free-space optical link between the first aerial vehicle and a second aerial vehicle that is operable in the aerial network. 18. A non-transitory computer-readable medium having program instructions stored thereon that are executable by at least one processor, the program instructions comprising: initially, when an aerial vehicle is at a location associated with a second geographic area in an aerial network, transmitting a second vehicle-state signal via a second communication channel, wherein the second communication channel is accessible to one or more other aerial vehicles that are operable in the aerial network, wherein the second vehicle-state signal indicates at least a portion of the vehicle-state profile for the second geographic area;subsequently determining that the aerial vehicle is at a location associated with the first geographic area in the aerial network;determining a vehicle-state profile for the first geographic area, wherein the vehicle-state profile comprises one or more state parameters for aerial vehicles operating in the first geographic area; andtransmitting a first vehicle-state signal via a first communication channel, wherein the first communication channel is accessible to one or more other aerial vehicles that are operable in the aerial network, wherein the first vehicle-state signal indicates at least a portion of the vehicle-state profile for the first geographic area. 19. The non-transitory computer-readable medium of claim 18, wherein the instructions for transmitting the first vehicle-state signal comprises instructions for broadcasting the first vehicle-state signal such that the vehicle-state signal is available to any aerial vehicle that is monitoring the first communication channel. 20. The non-transitory computer-readable medium of claim 18, wherein the aerial vehicle is a first aerial vehicle, the method further comprising: instructions for determining, at the first aerial vehicle, that a second aerial vehicle should be updated with the vehicle-state profile for the first geographic area; andinstructions for responsively sending the first vehicle-state signal to the second aerial vehicle.
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이 특허에 인용된 특허 (11)
Campbell J. Scott, Aerial communications network including a plurality of aerial platforms.
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