초록 ▼

Technology is described for enabling a reusable launch vehicle to compensate for wind prior to engaging propulsion during approach to landing. The technology can cause the reusable launch vehicle to begin un-powered descent; determine a first rotation angle of the reusable launch vehicle about a spe

Technology is described for enabling a reusable launch vehicle to compensate for wind prior to engaging propulsion during approach to landing. The technology can cause the reusable launch vehicle to begin un-powered descent; determine a first rotation angle of the reusable launch vehicle about a specified vertical descent path, the first rotation angle corresponding to a first attitude of the reusable launch vehicle selected to stabilize the reusable launch vehicle on the vertical descent path based on a wind speed and angle; and prior to engaging a propulsion device, command a second rotation angle for the reusable launch vehicle, the second rotation angle corresponding to a second attitude that, when the propulsion device is engaged, will cause the reusable launch vehicle to remain at least approximately at the vertical descent path.

대표청구항 ▼

1. A method performed by a reusable launch vehicle for compensating for wind prior to engaging propulsion during approach to landing in a powered slowdown configuration, comprising: beginning un-powered descent;determining a first rotation angle of the reusable launch vehicle about a specified verti

1. A method performed by a reusable launch vehicle for compensating for wind prior to engaging propulsion during approach to landing in a powered slowdown configuration, comprising: beginning un-powered descent;determining a first rotation angle of the reusable launch vehicle about a specified vertical descent path, the first rotation angle corresponding to a first attitude of the reusable launch vehicle selected to stabilize the reusable launch vehicle on the vertical descent path based on a wind speed and angle; andprior to engaging a main propulsion device in the powered slowdown configuration, commanding a second rotation angle for the reusable launch vehicle, the second rotation angle corresponding to a second attitude that, when the main propulsion device is engaged, will cause the reusable launch vehicle to remain at least approximately at the vertical descent path, wherein a thrust vector of the main propulsion device generally points towards a planetary source of gravity during all phases of flight. 2. The method of claim 1 further comprising engaging the main propulsion device. 3. The method of claim 1 wherein commanding the second rotation includes employing at least one propulsion device to cause the rotation prior to entering the powered slowdown configuration. 4. The method of claim 1 wherein commanding the second rotation includes employing at least one aerodynamic control surface to cause the rotation. 5. The method of claim 1 wherein commanding the second rotation includes selecting one of several available propulsion devices prior to entering the powered slowdown configuration. 6. The method of claim 5 further comprising selecting a first available propulsion device that is larger than a second available propulsion device when the wind speed and/or wind angle exceeds a threshold. 7. The method of claim 1 further comprising altering the second rotation angle based on a position of the reusable launch vehicle during descent as the reusable launch vehicle approaches landing site. 8. The method of claim 1, wherein the source of gravity is a planet from which the reusable launch vehicle launched. 9. The method of claim 1, wherein the source of gravity is Earth. 10. A computer-readable storage device for storing computer-executable instructions that, when executed, cause a reusable launch vehicle to compensate for wind prior to engaging propulsion during approach to landing in a powered slowdown configuration, comprising instructions for: determining a first rotation angle of the reusable launch vehicle about a specified vertical descent path, the first rotation angle corresponding to a first attitude of the reusable launch vehicle selected to stabilize the reusable launch vehicle on the vertical descent path based on a wind speed and angle; andprior to engaging a main propulsion device in the powered slowdown configuration, effecting rotation about a second angle for the reusable launch vehicle, the second rotation angle corresponding to a second attitude that, when the main propulsion device is engaged, will cause the reusable launch vehicle to remain at least approximately at the vertical descent path, wherein a thrust vector of the main propulsion device generally points towards a planetary source of gravity during all phases of flight. 11. The computer-readable storage medium of claim 10 further comprising instructions for engaging the main propulsion device. 12. The computer-readable storage medium of claim 10 wherein effecting the rotation about a second angle includes employing at least one propulsion device and one aerodynamic control surface to cause the rotation prior to entering the powered slowdown configuration. 13. The computer-readable storage medium of claim 10 wherein effecting the rotation about a second angle includes selecting one of several available propulsion devices prior to entering the powered slowdown configuration. 14. The computer-readable storage medium of claim 10 further comprising instructions for accounting for a lateral velocity to cause the reusable launch vehicle to reposition under power toward a specified location on a landing site. 15. The computer-readable storage medium of claim 10 further comprising instructions for altering the second rotation angle based on a position of the reusable launch vehicle during descent as the reusable launch vehicle approaches landing site. 16. A system for compensating for wind prior to engaging propulsion during approach to landing in a powered slowdown configuration by a reusable launch vehicle, comprising: a component configured to begin by the reusable launch vehicle an un-powered descent;a component configured to determine a first rotation angle of the reusable launch vehicle about a specified vertical descent path, the first rotation angle corresponding to a first attitude of the reusable launch vehicle selected to stabilize the reusable launch vehicle on the vertical descent path based on a wind speed and angle; anda component configured to, prior to engaging a main propulsion device in a powered slowdown configuration, command a second rotation angle for the reusable launch vehicle, the second rotation angle corresponding to a second attitude that, when the main propulsion device is engaged, will cause the reusable launch vehicle to remain at least approximately at the vertical descent path, wherein a thrust vector of the main propulsion device generally points towards a planetary source of gravity during all phases of flight. 17. The system of claim 16 further comprising at least secondary propulsion device, wherein the main propulsion device has a different maximum thrust capability than the secondary propulsion device. 18. The system of claim 17 further comprising a component that selects either the main propulsion device, the secondary propulsion device, or both propulsion devices based on the wind speed or wind angle. 19. The system of claim 18 wherein the secondary propulsion device is a small thruster and the main propulsion device is a main engine. 20. The system of claim 16 further comprising a component configured to rotate the reusable launch vehicle so that it is parallel and coincident with the vertical descent path. 21. The system of claim 16 further comprising a computing device configured to command any of the propulsion devices associated with the reusable launch vehicle, wherein the computing device has a processor and memory. 22. The system of claim 21 wherein the computing device is capable of registering wind information.