Control surfaces for use with high speed vehicles, and associated systems and methods

We claim: 1. An aerospace system, comprising: a space launch vehicle having an upper end, a lower end, a vehicle axis extending between the upper and lower ends, and one or more rocket nozzles positioned toward the lower end, wherein the launch vehicle is configured to implement a routine that includes: directing thrust from at least one of the one or more rocket nozzles to lift the launch vehicle during launch, the upper end being above the lower end during launch; subsequent to launch, descending and landing with the lower end below the upper end; and during descent, in which the lower end is below the upper end, shifting a center of pressure of the launch vehicle from a first position below a center of gravity of the vehicle to a second position above the center of gravity by moving a control surface carried toward the upper end of the launch vehicle from a first orientation in which the control surface is aligned with a direction of travel during ascent, to a second orientation that is different from the first orientation. 2. The aerospace system of claim 1 wherein the routine further includes directing thrust from the one or more rocket nozzles to decelerate the launch vehicle during descent. 3. The aerospace system of claim 1 wherein the control surface describes a first cross-sectional area generally normal to the vehicle axis toward the upper end of the launch vehicle during descent, the launch vehicle having a second cross-sectional area generally normal to the vehicle axis toward the lower end of the launch vehicle during descent, the second cross-sectional area being less than the first cross-sectional area. 4. The aerospace system of claim 1 wherein the control surface includes an outwardly facing, exposed surface that describes a first cross-sectional area generally normal to the vehicle axis toward the upper end of the launch vehicle during descent, the launch vehicle having a second cross-sectional area generally normal to the vehicle axis toward the lower end of the launch vehicle during descent, the second cross-sectional area being less than the first cross-sectional area. 5. The aerospace system of claim 1 wherein the control surface includes a deployable element that is stowed during ascent, and wherein shifting the center of pressure of the vehicle includes moving the deployable element from the stowed position to a deployed position. 6. The aerospace system of claim 1 wherein the routine further comprises directing thrust from the one or more rocket nozzles during landing. 7. The aerospace system of claim 1 wherein the control surface is tapered outwardly in a direction toward the upper end. 8. The aerospace system of claim 1 wherein the control surface includes a vane. 9. The aerospace system of claim 1 wherein the control surface includes a flare. 10. The aerospace system of claim 1 wherein the control surface is pivotably moveable relative to the launch vehicle. 11. The aerospace system of claim 1 wherein the control surface has air passages positioned to allow air to flow through the control surface. 12. The aerospace system of claim 1 wherein the launch vehicle further comprises one or more fins positioned toward the lower end and separate from the control surface. 13. The aerospace system of claim 1 wherein the launch vehicle further comprises one or more control fins positioned toward the lower end and separate from the control surface, and wherein the routine further includes controlling a direction of the launch vehicle during descent via the one or more control fins. 14. The aerospace system of claim 1 wherein the launch vehicle further comprises one or more control fins positioned toward the lower end and separate from the control surface, wherein the routine further includes controlling a direction of the launch vehicle during descent by pivoting the one or more control fins about a corresponding pivot axis extending outwardly from the vehicle axis. 15. The aerospace system of claim 1 wherein the launch vehicle further comprises one or more bidirectional control fins positioned toward the lower end and separate from the control surface, wherein the routine further includes controlling a direction of the launch vehicle during ascent via at least one of the one or more bidirectional control fins, and controlling a direction of the launch vehicle during descent via at least one of the one or more bidirectional control fins. 16. The aerospace system of claim 1 wherein the launch vehicle further comprises one or more bidirectional control fins positioned toward the lower end and separate from the control surface, wherein the routine further includes controlling a direction of the launch vehicle during ascent by pivoting at least one of the one or more of the bidirectional control fins about a corresponding pivot axis extending outwardly from the vehicle axis, and controlling a direction of the launch vehicle during descent by pivoting the at least one of the one or more bidirectional control fins about the corresponding pivot axis. 17. A system for providing access to space, the system comprising: a space launch vehicle, wherein the space launch vehicle includes one or more rocket engines; and a controller carried by the space launch vehicle, the controller being programmed with instructions that, when executed: direct thrust from a lower end of the launch vehicle to lift the launch vehicle during ascent, the launch vehicle having an upper end positioned above the lower end during ascent; during descent, shift a center of pressure of the launch vehicle from a first position below a center of gravity of the launch vehicle to a second position above the center of gravity by moving a control surface from a stowed position to a deployed position after launch, wherein the upper end of the vehicle is positioned above the lower end during descent, wherein the control surface is positioned toward the upper end, the stowed position comprises the control surface being aligned with a direction of travel during ascent, and the deployed position comprises the control surface being oriented to extend outwardly from the space launch vehicle; and direct thrust from the lower end of the launch vehicle to decelerate the launch vehicle during descent. 18. The system of claim 17 wherein the control surface is moved from the stowed position to the deployed position during descent. 19. The system of claim 17 wherein the center of gravity is positioned between the control surface and the rocket engines. 20. The system of claim 17 wherein the control surface is positioned above the center of gravity during descent. 21. The system of claim 17 wherein the center of pressure is aft of the center of gravity during vehicle ascent, and wherein the center of pressure is aft of the center of gravity during vehicle descent. 22. The system of claim 17 wherein moving the control surface from the stowed position to the deployed position includes pivoting the control surface relative to the launch vehicle. 23. The system of claim 17 wherein moving the control surface from the stowed position to the deployed position includes pivoting the control surface outwardly relative to the launch vehicle. 24. The system of claim 17 wherein moving the control surface from the stowed position to the deployed position includes moving a fin. 25. The system of claim 17 wherein moving the control surface from the stowed p