초록 ▼

An air vehicle, such as a missile, for example an interceptor, includes control surfaces and a vectored thrust system, both used for steering the missile. A controller is operatively coupled to both steering mechanisms, and is configured to operate in a low dynamic pressure mode, which uses the vect

An air vehicle, such as a missile, for example an interceptor, includes control surfaces and a vectored thrust system, both used for steering the missile. A controller is operatively coupled to both steering mechanisms, and is configured to operate in a low dynamic pressure mode, which uses the vectored thrust system for at least part of the steering, only when the dynamic pressure is low, such as when the missile is at high altitude. At higher dynamic pressure, such as at lower altitude, the controller is configured to operate in a high dynamic pressure mode that uses only the control surfaces for steering. This allows the interceptor to operate at higher altitudes than interceptors that use only control surfaces for steering during flight. During flight for a high altitude interception the missile shifts from the high dynamic pressure mode to the low dynamic pressure mode.

대표청구항 ▼

1. An air vehicle comprising: movable control surfaces for steering the air vehicle;a thrust system that provides vectored thrust for steering the air vehicle; anda controller operatively coupled to the control surfaces and the vectored thrust system;wherein the thrust system is a multiple pulse roc

1. An air vehicle comprising: movable control surfaces for steering the air vehicle;a thrust system that provides vectored thrust for steering the air vehicle; anda controller operatively coupled to the control surfaces and the vectored thrust system;wherein the thrust system is a multiple pulse rocket motor that is capable of providing multiple thrust pulses at different times, the thrust system including fuel and a nozzle operatively coupled to the fuel to produce thrust in various directions; andwherein the controller shifts during flight of the air vehicle from a high dynamic pressure mode, in which the controller uses only the control surfaces to steer the air vehicle, to a low dynamic pressure mode, in which the controller uses the vectored thrust system to provide at least part of the steering of the air vehicle. 2. The air vehicle of claim 1, wherein the thrust system also provides thrust to accelerate the air vehicle toward a target. 3. The air vehicle of claim 1, wherein the nozzle is a gimbaled nozzle. 4. The air vehicle of claim 1, wherein the control surfaces are movably coupled to a fuselage of the air vehicle. 5. The air vehicle of claim 4, wherein the control surfaces include canards that are movable relative to the fuselage. 6. The air vehicle of claim 4, wherein the control surfaces include fins that are movable relative to the fuselage. 7. The air vehicle of claim 1, wherein the air vehicle is an interceptor that includes a lethality enhancement device for defeating an airborne device that is intercepted by the air vehicle. 8. The air vehicle of claim 1, wherein the controller uses dynamic pressure, as a function of at least altitude of the air vehicle and airspeed of the air vehicle, to shift between the modes. 9. The air vehicle of claim 1, wherein the controller, in the low dynamic pressure mode, also uses the control surfaces to steer the air vehicle. 10. An air vehicle comprising: movable control surfaces for steering the air vehicle;a thrust system that provides vectored thrust for steering the air vehicle; anda controller operatively coupled to the control surfaces and the vectored thrust system;wherein the thrust system includes fuel and a nozzle operatively coupled to the fuel to produce thrust in various directions;wherein the fuel has multiple solid fuel portions that are separately ignitable, so as to produce multiple thrust pulses at different times; andwherein the controller shifts during flight of the air vehicle from a high dynamic pressure mode, in which the controller uses only the control surfaces to steer the air vehicle, to a low dynamic pressure mode, in which the controller uses the vectored thrust system to provide at least part of the steering of the air vehicle. 11. The air vehicle of claim 10, further comprising partitions between the fuel portions. 12. A method of operating an air vehicle, the method comprising: launching the air vehicle; andafter the launching, steering the interceptor both in a high dynamic pressure mode, in which the steering involves only movable control surfaces of the air vehicle to steer the air vehicle, and in a low dynamic pressure mode, in which the steering uses a vectored thrust system of the air vehicle to provide at least part of the steering of the air vehicle;wherein the thrust system is a multiple pulse rocket motor that is capable of providing multiple thrust pulses at different times;wherein the steering includes shifting between the high dynamic pressure mode and the low dynamic pressure mode during flight of the air vehicle: andwherein the steering in the low dynamic pressure mode includes saving at least one of the thrust pulses for use in a terminal flight portion that includes guiding the air vehicle to a target. 13. The method of claim 12, wherein the shifting includes a shifting from the high dynamic pressure mode to the low dynamic pressure mode. 14. The method of claim 13, wherein the shifting from the high dynamic pressure mode to the low dynamic pressure mode occurs while the air vehicle is at an altitude of at least 20 kilometers. 15. The method of claim 12, wherein the shifting includes shifting between the high dynamic pressure mode and the low dynamic pressure mode multiple times during the flight of the air vehicle. 16. The method of claim 12, wherein the target is a moving target; andwherein the guiding the air vehicle to the target includes using the at least one of the thrust pulses to maneuver the air vehicle, in the terminal flight portion, to neutralize the moving target. 17. The method of claim 12, wherein the launching includes accelerating the air vehicle using the thrust system. 18. The method of claim 17, further comprising changing orientation of the air vehicle, using the vectored thrust system, after the launching and prior to the steering.