Determining VTOL Departure Time in an Aviation Transport Network for Efficient Resource Management

1 - 20 . (canceled) 21 . A computer-implemented method, comprising: accessing data corresponding to a status for a fleet of aircraft, the current aircraft status comprising one or more of a current location, a current battery level, and an airborne or grounded indication for each aircraft of the fleet of aircraft; accessing data corresponding to current routes for the fleet of aircraft, the current routes comprising one or more of a destination, a time of arrival, and a number of passengers for each aircraft of the fleet of aircraft; accessing data corresponding to current demand for the fleet of aircraft, the current demand comprising a plurality of requests for transport services from a respective origin to a respective destination; computing estimated future demand for the fleet of aircraft based on the current routes for the fleet of aircraft, the future demand comprising a plurality of predicted requests for future transport services from a respective origin to a respective destination; and computing at least one updated route for the fleet of aircraft based on the current demand and the estimated future demand; and transmitting the at least one updated route to each respective aircraft of the fleet of aircraft. 22 . The computer-implemented method of claim 21 , wherein computing the estimated future demand comprises computing the estimated future demand with a model trained on routes serviced by the fleet of aircraft. 23 . The computer-implemented method of claim 21 , wherein the at least one updated route reduces total power usage of the fleet of aircraft relative to the current routes for the fleet of aircraft after an unexpected failure in another mode of transport. 24 . The computer-implemented method of claim 21 , wherein accessing the data corresponding to the status for the fleet of aircraft, accessing the data corresponding to the current routes for the fleet of aircraft, accessing the data corresponding to the current demand for the fleet of aircraft, computing the estimated future demand for the fleet of aircraft, and computing the at least one updated route for the fleet of aircraft are repeated no less than every five minutes such that the at least one updated route reduces total power usage of the fleet of aircraft relative to the current routes for the fleet of aircraft after an increase in requests for transport services for the fleet of aircraft. 25 . The computer-implemented method of claim 21 , wherein accessing the data corresponding to the status for the fleet of aircraft comprises receiving the status for an aircraft of the fleet of aircraft from the aircraft via a wireless network. 26 . The computer-implemented method of claim 21 , wherein accessing the data corresponding to the status for the fleet of aircraft comprises estimating the status for the aircraft of the fleet of aircraft based on a last known status for the aircraft and the current route for the aircraft. 27 . The computer-implemented method of claim 21 , wherein accessing the data corresponding to the current routes for the fleet of aircraft comprises accessing the data corresponding to the current routes for the fleet of aircraft from a routing data store located offboard the fleet of aircraft. 28 . The computer-implemented method of claim 21 , wherein the data corresponding to the current demand for the fleet of aircraft comprises a set of transport requests received from user client devices. 29 . The computer-implemented method of claim 21 , wherein computing the estimated future demand for the fleet of aircraft comprises computing the estimated future demand for the fleet of aircraft within a time period that is no greater than four hours. 30 . The computer-implemented method of claim 21 , wherein computing the at least one updated route for the fleet of aircraft comprises computing a plurality of updated routes for the fleet of aircraft based on both actual transport requests of the current demand and predicted transport requests of the estimated future demand. 31 . A system for data transmission between aircraft, comprising: one or more processors; and one or more non-transitory computer-readable media that store instructions that are executable by the one or more processors to perform operations, the operations comprising accessing data corresponding to a status for a fleet of aircraft, the current aircraft status comprising one or more of a current location, a current battery level, and an airborne or grounded indication for each aircraft of the fleet of aircraft, accessing data corresponding to current routes for the fleet of aircraft, the current routes comprising one or more of a destination, a time of arrival, and a number of passengers for each aircraft of the fleet of aircraft, accessing data corresponding to current demand for the fleet of aircraft, the current demand comprising a plurality of requests for transport services from a respective origin to a respective destination, computing estimated future demand for the fleet of aircraft based on the current routes for the fleet of aircraft, the future demand comprising a plurality of predicted requests for future transport services from a respective origin to a respective destination, and computing at least one updated route for the fleet of aircraft based on the current demand and the estimated future demand, and transmitting the at least one updated route to each respective aircraft of the fleet of aircraft. 32 . The system of claim 31 , wherein computing the estimated future demand comprises computing the estimated future demand with a model trained on routes serviced by the fleet of aircraft. 33 . The system of claim 31 , wherein the at least one updated route reduces total power usage of the fleet of aircraft relative to the current routes for the fleet of aircraft after an unexpected failure in another mode of transport. 34 . The system of claim 31 , wherein accessing the data corresponding to the status for the fleet of aircraft, accessing the data corresponding to the current routes for the fleet of aircraft, accessing the data corresponding to the current demand for the fleet of aircraft, computing the estimated future demand for the fleet of aircraft, and computing the at least one updated route for the fleet of aircraft are repeated no less than every five minutes such that the at least one updated route reduces total power usage of the fleet of aircraft relative to the current routes for the fleet of aircraft after an increase in requests for transport services for the fleet of aircraft. 35 . The system of claim 31 , wherein accessing the data corresponding to the status for the fleet of aircraft comprises receiving the status for an aircraft of the fleet of aircraft from the aircraft via a wireless network. 36 . The system of claim 31 , wherein accessing the data corresponding to the status for the fleet of aircraft comprises estimating the status for the aircraft of the fleet of aircraft based on a last known status for the aircraft and the current route for the aircraft. 37 . The system of claim 31 , wherein accessing the data corresponding to the current routes for the fleet of aircraft comprises accessing the data corresponding to the current routes for the fleet of aircraft from a routing data store located offboard the fleet of aircraft. 38 . The system of claim 31 , wherein the data corresponding to the current demand for the fleet of aircraft comprises a set of transport requests received from user client devices. 3