A simpler, smaller, less costly intercepting vehicle is provided. For example, a highly scalable intercepting vehicle may include a single axial rocket motor and a body-fixed, wide field of view (FOV) sensor unit to accommodate attitude changes required to steer the intercepting vehicle. This interc
A simpler, smaller, less costly intercepting vehicle is provided. For example, a highly scalable intercepting vehicle may include a single axial rocket motor and a body-fixed, wide field of view (FOV) sensor unit to accommodate attitude changes required to steer the intercepting vehicle. This intercepting vehicle may be much smaller and less costly than conventional intercepting vehicles.
대표청구항▼
1. An apparatus, comprising: a computing system configured to sequentially or synchronously operate at least one body-fixed sensor unit, an inertial measurement unit, an attitude control system, and at least one axial rocket motor, such that thrust from the at least one axial rocket motor is applied
1. An apparatus, comprising: a computing system configured to sequentially or synchronously operate at least one body-fixed sensor unit, an inertial measurement unit, an attitude control system, and at least one axial rocket motor, such that thrust from the at least one axial rocket motor is applied in a direction that allows the apparatus to intercept a target or applied in a direction of an estimated intercept point, whereinthe at least one body-fixed sensor unit comprising a wide field of view to detect the target. 2. The apparatus of claim 1, wherein the at least one body-fixed sensor unit is configured to point to the target by adjusting an attitude of the apparatus such that the target is periodically within the field of view prior to reaching the estimated intercept point. 3. The apparatus of claim 1, further comprising: a communication unit configured to receive data from an external system, whereinthe data comprises information to estimate a location, a location and velocity, or a location, velocity and acceleration, of the target and the apparatus in a same inertial reference frame. 4. The apparatus of claim 1, wherein the inertial measurement unit is configured to measure an attitude rate or an attitude and the attitude rate of the apparatus. 5. The apparatus of claim 4, wherein the inertial measurement unit is further configured to measure an acceleration, a velocity and acceleration, or a location, velocity, and acceleration of the apparatus. 6. The apparatus of claim 1, further comprising: a star tracker configured to measure an attitude, or the attitude and an attitude rate, of the apparatus. 7. The apparatus of claim 1, wherein the at least one body-fixed sensor unit comprises a star tracker configured to measure an attitude, or the attitude and an attitude rate, of the apparatus. 8. The apparatus of claim 1, wherein the at least one body-fixed sensor unit is further configured to measure a direction vector, an angular velocity vector, or both, of a line of sight vector relative to the apparatus, the line of sight vector identifying a direction from the apparatus to a location of the target. 9. The apparatus of claim 1, wherein the computing system is further configured to determine an inertial angular velocity vector of a line of sight vector based on an angular velocity vector of a line of sight vector relative to the apparatus and on an inertial angular velocity vector of the apparatus. 10. The apparatus of claim 9, wherein the computing system is further configured to compute a guidance command, calculate an acceleration vector, and implement a maneuver that causes the apparatus to intercept the target subject to an attitude constraint applied to the apparatus. 11. The apparatus of claim 9, wherein the computing system is configured to compute a guidance command and implement a maneuver subject to a constraint that the target is periodically within the field of view of the at least one body-fixed sensor unit. 12. A method, comprising: detecting a target by a body-fixed sensor unit onboard an intercepting vehicle;rotating, by a computing system, at least one axial rocket motor of the intercepting vehicle such that the target periodically remains within a field of view of the body-fixed sensor unit; andsimultaneously or synchronously operating, by the computing system, the body-fixed sensor unit, an inertial measurement unit, an attitude control system, and the at least one axial rocket motor such that thrust from the at least one axial rocket motor is applied in a direction that allows the intercepting vehicle to intercept the target. 13. The method of claim 12, wherein the rotating of the at least one axial rocket motor comprises: rotating, by the attitude control system, the at least one axial rocket motor such that the intercepting vehicle accelerates in a direction to intercept the target while periodically maintaining the target within the field of view of the body-fixed sensor unit during rotation. 14. The method of claim 12, further comprising: rotating the intercepting vehicle, by the attitude control system using a thrust vector control system or a non-thrust vector control system. 15. An intercepting vehicle, comprising: a sensor unit comprising a wide field of view and configured to detect a target; anda computing system configured to simultaneously or synchronously operate the sensor unit, an inertial measurement unit, an attitude control system, and at least one axial rocket motor such that thrust from the at least one axial rocket motor is applied in a direction that allows the intercepting vehicle to intercept the target. 16. The intercepting vehicle of claim 15, wherein the sensor unit comprises a body-fixed sensor unit or a body-mounted sensor unit. 17. The intercepting vehicle of claim 15, wherein the at least one axial rocket motor comprises a solid-fueled rocket motor, a liquid-fueled rocket motor, a hybrid rocket motor, an electric rocket motor, or a gas rocket motor. 18. The intercepting vehicle of claim 15, further comprising: at least one hollow tube attached to the at least one single rocket motor configured to pass wires from an electronics unit to a thrust vector control system to power and control the thrust vector control system. 19. The intercepting vehicle of claim 15, wherein the sensor unit is further configured to measure a direction vector, an angular velocity vector, or both, of a line of sight vector from the intercepting vehicle to the target. 20. The intercepting vehicle of claim 15, wherein the attitude control system is configured to perform attitude adjustment of the intercepting vehicle to intercept the target while constraining the target to periodically remain within the wide field of view of the sensor unit. 21. The intercepting vehicle of claim 20, wherein the attitude control system comprises a thrust vector control system for actuation. 22. The intercepting vehicle of claim 20, wherein the attitude control system comprises a non-thrust vector control system for actuation. 23. The intercepting vehicle of claim 20, wherein the attitude control system comprises a combination of a thrust vector control system and a non-thrust vector control system for actuation. 24. The intercepting vehicle of claim 20, wherein the attitude control system is configured to rotate the intercepting vehicle such that the intercepting vehicle accelerates in a direction to align a relative velocity vector with a line of sight vector. 25. The intercepting vehicle of claim 15, wherein the inertial measurement unit is configured to measure an attitude rate or an attitude and the attitude rate of the intercepting vehicle. 26. The intercepting vehicle of claim 15, wherein the inertial measurement unit is further configured to measure an acceleration, a velocity and acceleration, or a location, velocity, and acceleration of the intercepting vehicle.
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