Underwater celestial navigation beacon

What is claimed is: 1. An underwater celestial navigation beacon configured to provide position information, the underwater celestial navigation beacon comprising: a non-transitory machine readable storage medium configured to store an astronomical model of the moon; an inertial measurement unit (IMU) operable to capture IMU data that includes three-axis acceleration data and three-axis rate gyroscopic data; and a processor configured to: determine a rotation of the earth using the three-axis rate gyroscopic data in order to resolve the latitude of the underwater celestial navigation beacon; determine a longitude of the underwater celestial navigation beacon based on a gravitational pull of the moon, using the three-axis acceleration data and the astronomical model of the moon; and determine the position information for the underwater celestial navigation beacon based on the latitude and longitude, wherein the underwater celestial navigation beacon is configured to enter into a low power mode after determining the position information. 2. The underwater celestial navigation beacon of claim 1 , wherein the controller is further configured to: determine the gravitational pull of the moon around the earth as a function of time based on the three-axis acceleration data, wherein oscillations in acceleration as indicated by the three-axis acceleration data are caused by the gravitational pull of the moon; determine a phase of the moon as a function of time based on the gravitational pull of the moon; and resolve the longitude of the underwater celestial navigation beacon using the phase of the moon with the astronomical model of the moon, wherein the astronomical model of the moon indicates known positions of the moon over a period of time. 3. The underwater celestial navigation beacon of claim 1 , wherein the controller is further configured to determine multiple phase measurements of the moon over two or more cycles of the moon to resolve the longitude of the underwater celestial navigation beacon. 4. The underwater celestial navigation beacon of claim 1 , further comprising an acoustic transponder configured to: receive an awake message from an underwater vehicle; and transmit the position information to the underwater vehicle in response to receiving the awake message, wherein the position information enables the underwater vehicle to determine its position based on the position information associated with the underwater celestial navigation beacon and adjust for inertial navigation system (INS) drift at the underwater vehicle. 5. The underwater celestial navigation beacon of claim 1 , wherein the underwater celestial navigation beacon is stationary on an ocean floor. 6. The underwater celestial navigation beacon of claim 1 , wherein the underwater celestial navigation beacon is included in an array of underwater beacons that provide position information to an underwater vehicle. 7. The underwater celestial navigation beacon of claim 1 , wherein the controller is further configured to provide the position information underwater where global positioning system (GPS) signals are absent. 8. The underwater celestial navigation beacon of claim 1 , wherein the controller is further configured to: receive, from the IMU, additional IMU data after the position information for the underwater celestial navigation beacon is determined; determine that the underwater celestial navigation beacon has been potentially tampered with based on the additional IMU data; and send a notification indicating a potential tampering of the underwater celestial navigation beacon. 9. A system for navigating an underwater vehicle, the system comprising: an underwater vehicle that includes an acoustic transponder; and an underwater celestial navigation beacon, comprising: non-transitory machine readable storage medium configured to store an astronomical model of the moon; an inertial measurement unit (IMU) operable to capture IMU data that includes three-axis acceleration data and three-axis rate gyroscopic data; a processor configured to: determine a rotation of the earth using the three-axis rate gyroscopic data in order to resolve the latitude of the underwater celestial navigation beacon; determine a longitude of the underwater celestial navigation beacon based on a gravitational pull of the moon, using the three-axis acceleration data and the astronomical model of the moon; and determine the position information for the underwater celestial navigation beacon based on the latitude and longitude; and an acoustic transponder configured to transmit the position information to the underwater vehicle, wherein the underwater celestial navigation beacon is configured to enter into a low power mode after determining the position information. 10. The system of claim 9 , wherein: the acoustic transponder of the underwater vehicle is configured to send an awake message to wake up the underwater celestial navigation beacon; and the acoustic transponder of the underwater celestial navigation beacon is configured to: receive the awake message from the underwater vehicle; and transmit the position information to the underwater vehicle in response to receiving the awake message. 11. The system of claim 9 , wherein the underwater vehicle is configured to: determine its position based on the position information received from the underwater celestial navigation beacon; and adjust for inertial navigation system (INS) drift at the underwater vehicle. 12. The system of claim 9 , further comprising: an array of underwater celestial navigation beacons along a path, wherein the underwater vehicle is configured to communicate with the array of underwater celestial navigation beacons when traveling along the path to resolve a position for the underwater vehicle. 13. A system for facilitating underwater position determination for underwater vehicles along a path, the system comprising: an array of underwater celestial navigation beacons that are located in different positions along a path, the array including an underwater celestial navigation beacon comprising: a non-transitory machine readable storage medium configured to store an astronomical model of the moon; an inertial measurement unit (IMU) operable to capture IMU data that includes three-axis acceleration data and three-axis rate gyroscopic data; and a processor configured to: determine a rotation of the earth using the three-axis rate gyroscopic data in order to resolve the latitude of the underwater celestial navigation beacon; determine a longitude of the underwater celestial navigation beacon based on a gravitational pull of the moon, using three-axis acceleration data and an astronomical model of the moon; and determine position information for the underwater celestial navigation beacon based on the latitude and longitude; and an underwater vehicle configured to receive position information from the underwater celestial navigation beacons in the array at different times when traveling along the path, wherein the underwater celestial navigation beacon is configured to enter into a low power mode after determining the position information. 14. The system of claim 13 , wherein the underwater celestial navigation beacon is further configured to: determine the gravitational pull of the moon around the earth as a function of time based on the three-axis acceleration data, wherein oscillations in acceleration as indicated by the three-axis acceleration data are caused by the gravitational pull of the moon; determine a phase of the moon as a function of time based on the