초록 ▼

Methods are described for launching multiple space vehicles. A first space vehicle and a second space vehicle can be detachably attached to a launch vehicle. The first space vehicle is for an orbit of a first desired altitude in a first desired orbital plane. The second vehicle is for an orbit of a

Methods are described for launching multiple space vehicles. A first space vehicle and a second space vehicle can be detachably attached to a launch vehicle. The first space vehicle is for an orbit of a first desired altitude in a first desired orbital plane. The second vehicle is for an orbit of a second desired altitude in a second desired orbital plane. The launch vehicle with the first and second space vehicles may be launched into a first orbit in or near the first desired orbital plane. The second space vehicle may be released in the first orbit. When the orbital plane of the second space vehicle coincides with the second desired orbital plane, the second space vehicle may be transferred to a transfer orbit. The second space vehicle may be transferred to the orbit of the second desired altitude in the second desired orbital plane.

대표청구항 ▼

What is claimed is: 1. A method for launching a single first space vehicle and a single second space vehicle, the first space vehicle designed to carry out its own mission in a first final destination orbit in a first final destination orbital plane and having its own one or more first rocket engin

What is claimed is: 1. A method for launching a single first space vehicle and a single second space vehicle, the first space vehicle designed to carry out its own mission in a first final destination orbit in a first final destination orbital plane and having its own one or more first rocket engines, the second space vehicle designed to carry out its own mission in a second final destination orbit in a second final destination orbital plane and having its own one or more second rocket engines, the method comprising: determining a first orbit having a first perigee altitude and a first apogee altitude, into which the launch vehicle is to be launched and where the second space vehicle is to be released, based on an orbital regression rate of the second space vehicle to insert the second space vehicle from the first final destination orbital plane into the second final destination orbital plane, based on perturbations produced by an oblateness of the earth, without utilizing a launch vehicle or the one or more second rocket engines of the second space vehicle; launching the launch vehicle with the first and second space vehicles into the first orbit in the first final destination orbital plane of the first space vehicle; releasing the second space vehicle from the launch vehicle, in the first orbit in the first final destination orbital plane, while the first space vehicle is attached to the launch vehicle; determining when an orbital plane of the second space vehicle coincides with the second final destination orbital plane of the second space vehicle; transferring the second space vehicle from the first final destination orbital plane to the second final destination orbital plane, without utilizing the launch vehicle or the one or more second rocket engines of the second space vehicle; firing the one or more second rocket engines of the second space vehicle, when the second space vehicle is in the second final destination orbital plane, to achieve a transfer orbit; determining when to fire the one or more second rocket engines of the second space vehicle to achieve the second final destination orbit; firing the one or more second rocket engines of the second space vehicle at a time determined to achieve the second final destination orbit; and performing, by the second space vehicle, its own mission at the second final destination orbit in the second final destination orbital plane, wherein the first final destination orbital plane is different from the second final destination orbital plane. 2. The method of claim 1, further comprising: releasing the first space vehicle from the launch vehicle, in a second orbit in the first final destination orbital plane. 3. The method of claim 2, further comprising: firing the one or more first rocket engines of the first space vehicle to achieve the first final destination orbit in the first final destination orbital plane. 4. The method of claim 3, further comprising: performing, by the first space vehicle, its own mission at the first final destination orbit in the first final destination orbital plane. 5. The method of claim 3, wherein the firing of the one or more first rocket engines is performed before completing the transferring of the second space vehicle to the second final destination orbital plane, and wherein the first space vehicle achieves the first final destination orbit in the first final destination orbital plane before the second space vehicle is transferred to the second final destination orbital plane. 6. The method of claim 3, wherein the firing of the one or more first rocket engines is performed during the transferring of the second space vehicle from the first final destination orbital plane to the second final destination orbital plane. 7. The method of claim 2, wherein the second orbit is characterized by a second perigee altitude and a second apogee altitude, and wherein the method further comprises: determining the second perigee altitude based on capabilities of the launch vehicle and capabilities of the first space vehicle; selecting the second apogee altitude that is substantially the same as the first final destination orbit; and transferring the launch vehicle into the second orbit prior to completing the step of releasing the first space vehicle. 8. The method of claim 3, wherein the firing of the one or more first rocket engines comprises: determining when to fire propulsive rocket engines of the first space vehicle to achieve the first final destination orbit in the first final destination orbital plane; and firing the propulsive rocket engines of the first space vehicle, at multiple times determined by the determining when to fire the propulsive rocket engines, to achieve the first final destination orbit in the first final destination orbital plane. 9. The method of claim 1, wherein the firing of the one or more second rocket engines of the second space vehicle to achieve the transfer orbit, comprises: determining when to fire the one or more second rocket engines of the second space vehicle to achieve the transfer orbit; and firing the one or more second rocket engines of the second space vehicle, at multiple times determined by the determining when to fire the one or more second rocket engines of the second space vehicle to achieve the transfer orbit. 10. The method of claim 1, wherein the firing of the one or more second rocket engines of the second space vehicle to achieve the second final destination orbit, comprises: firing the one or more second rocket engines of the second space vehicle at multiple times determined by the determining when to fire the one or more second rocket engines of the second space vehicle to achieve the second final destination orbit. 11. The method of claim 1, wherein the determining the first orbit comprises: determining the first orbit having the first perigee altitude and the first apogee altitude based on capabilities of the launch vehicle, capabilities of the second space vehicle, and the orbital regression rate appropriate for inserting the second space vehicle into the second final destination orbital plane. 12. The method of claim 1, wherein the first orbit is a low earth orbit. 13. The method of claim 1, further comprising: releasing the first space vehicle from the launch vehicle, in the first orbit in the first final destination orbital plane. 14. The method of claim 2, wherein the determining of the first orbit is performed before the launching, and wherein the releasing of the first space vehicle is performed after the releasing of the second space vehicle and before completing the transferring of the second space vehicle to the second final destination orbital plane. 15. The method of claim 3, wherein the first orbit of the second space vehicle is elliptic, the transfer orbit of the second space vehicle is elliptic, and the second final destination orbit of the second space vehicle is circular, wherein the second orbit of the first space vehicle is elliptic, and the first final destination orbit of the first space vehicle is circular, wherein the first orbit is different from the second orbit, wherein the first perigee altitude of the first orbit is the same as a perigee altitude of the transfer orbit, wherein an apogee altitude of the transfer orbit is the same as an apogee altitude of the second final destination orbit, and wherein an apogee altitude of the second orbit is the same as an apogee altitude of the first final destination orbit. 16. The method of claim 1, wherein the second space vehicle has an ADS (attitude determination subsystem), and wherein the performing, by the second space vehicle, its own mission comprises: performing, by the second space vehicle, attitude determination utilizing the ADS. 17. The method of claim 1, wherein the second space vehicle has a communication module having TT&C (telemetry tracking & command) and C&DH (command and data handling), and wherein the performing, by the second space vehicle, its own mission comprises: performing, by the second space vehicle, telemetry tracking and command; and performing, by the second space vehicle, command and data handling. 18. The method of claim 1, wherein the second space vehicle has an EC antenna (earth coverage antenna), and wherein the performing, by the second space vehicle, its own mission comprises: performing, by the second space vehicle, communication utilizing an earth coverage antenna. 19. The method of claim 1, wherein the second space vehicle has NDS (nuclear detonation detection system) electronics, and wherein the performing, by the second space vehicle, its own mission comprises: performing, by the second space vehicle, nuclear detonation detection. 20. The method of claim 1, wherein the second space vehicle has waveguides, and wherein the performing, by the second space vehicle, its own mission comprises utilizing waveguides.