System and method of hypersonic object tracking

What is claimed is: 1. A method of tracking a hypersonic object over its full flightpath comprising: providing a plurality of observers having at least one sensor configured to provide measurements of the hypersonic object such that each of the observers is configured to independently measure any combination of range, angles, Doppler, and angle rates; transmitting, by the observers, data including the measurements of the hypersonic object and uncertainties of the hypersonic object to a processing unit as the hypersonic object undergoes three phases including a boost phase, a ballistic phase, and a hypersonic glide phase; and during each phase, repeating the following steps over a plurality of time steps to track the hypersonic object: selecting a dynamics model representative of expected object kinematics during said phase; using an unscented Kalman filter to predict a future state and a covariance using the dynamics model that was selected; and using the unscented Kalman filter to update the future state and covariance that were predicted based on the measurements of the hypersonic object. 2. The method of claim 1 , wherein tracking the hypersonic object includes integrating a plurality of object dynamics and measurement models consisting of a dissimilar number of states, parameters, reference frames, and time units together using the unscented Kalman filter, and each model functions in a native coordinate system. 3. The method of claim 2 , wherein each model is interchangeable via transformation of a state of the model and uncertainty between coordinate systems, allowing for model switching between time steps. 4. The method of claim 1 , wherein: during the boost phase, the dynamics model selected accounts for thrust and gravitational forces on the hypersonic objection; during the ballistic phase, the dynamics model selected accounts for gravitational forces on the hypersonic object; and during the glide phase, the dynamics model selected accounts for aerodynamic forces. 5. The method of claim 4 , wherein: the phases further include a terminal phase; and during the terminal phase, the dynamics model selected accounts for random acceleration and gravitational forces. 6. The method of claim 1 , wherein the observers include a plurality of satellites forming a constellation of low earth satellites which observe the hypersonic object from different positions. 7. The method of claim 6 , wherein the satellites include: a first satellite having a sensor configured to measure an angle of the hypersonic object only; a second satellite having a sensor configured to measure an angle of the hypersonic object only; a third satellite having sensors configured to measure a range and an angle of the hypersonic object. 8. The method of claim 1 , wherein the observers include at least one ground-based observer including sensors configured to measure range, azimuth, and elevation of the hypersonic object. 9. The method of claim 1 , wherein the unscented Kalman filter is either a 12 state or 9 state boost-phase unscented Kalman filter. 10. A system configured to track a hypersonic object over its full flightpath comprising: at least one observer, each observer including at least one sensor configured to provide measurements of the hypersonic object such that each observer is configured to independently measure any combination of range, angles, Doppler, and angle rates; and a processing unit, wherein each observer is configured to transmit data including the measurements of the hypersonic object and uncertainties of the hypersonic object to the processing unit as the hypersonic object undergoes three phases including a boost phase, a ballistic phase, and a hypersonic glide phase, wherein, during each phase, the processing unit is configured to repeat the following steps over a plurality of time steps to track the hypersonic object: selecting a dynamics model representative of expected object kinematics during said phase; using an unscented Kalman filter to predict a future state and a covariance using the dynamics model that was selected; and using the unscented Kalman filter to update the future state and covariance that were predicted based on the measurements of the hypersonic object. 11. The system of claim 10 , wherein the processing unit is further configured to track the hypersonic object by integrating a plurality of object dynamics and measurement models consisting of a dissimilar number of states, parameters, reference frames, and time units together using the unscented Kalman filter, and each model functions in a native coordinate system. 12. The system of claim 11 , wherein the processing unit is configured such that each model is interchangeable via transformation of a state of the model and uncertainty between coordinate systems, allowing for switching between time steps. 13. The system of claim 10 , wherein the processing unit is further configured such that: during the boost phase, the dynamics model selected accounts for thrust and gravitational forces on the hypersonic objection; during the ballistic phase, the dynamics model selected accounts for gravitational forces on the hypersonic object; and during the glide phase, the dynamics model selected accounts for aerodynamic forces. 14. The system of claim 13 , wherein: the phases further include a terminal phase; and during the terminal phase, the dynamics model selected by the processing unit accounts for random acceleration and gravitational forces. 15. The system of claim 10 , wherein the observers include a plurality of satellites forming a constellation of low earth satellites which observe the hypersonic object from different positions. 16. The system of claim 15 , wherein the satellites include: a first satellite having a sensor configured to measure an angle of the hypersonic object only; a second satellite having a sensor configured to measure an angle of the hypersonic object only; a third satellite having sensors configured to measure a range and an angle of the hypersonic object. 17. The system of claim 10 , wherein the observers may include ground-based observers with sensors configured to measure any combination of range, azimuth, elevation, Doppler, and angular rates of the hypersonic object. 18. The system of claim 10 , wherein the unscented Kalman filter is either a 12 state or 9 state boost-phase unscented Kalman filter.