Oceanic eddy detection from two-dimensional sea level topography gradients

What is claimed is: 1. An eddy detector device for detecting an eddy, the eddy detector device comprising: a processing device; and a memory coupled to the processing device, the memory containing executable instructions, wherein execution of the executable instructions, by the processing device, causes the processing device to perform operations comprising: receiving, using the processing device, climatological data, determining, using the processing device, a base domain for detecting the eddy, determining, using the processing device, a center of the eddy within the base domain, wherein determining the center of the eddy comprises determining a maximum absolute dynamic topography (ADT) observation within the base domain, determining, using the processing device, spatial criteria for finding edges of the eddy, wherein determining the spatial criteria for finding edges of the eddy comprises determining a plurality of outward ADT gradients from the center of the eddy in a plurality of directions, wherein the plurality of directions correspond to a plurality of radial angles around a circle centered at the center of the eddy, determining, using the processing device, temporal criteria for finding edges of the eddy, determining, using the processing device, potential edge points of the eddy based on the spatial criteria and the temporal criteria, and generating, using the processing device, a polygon around the potential edge points. 2. The eddy detector device of claim 1 , wherein the base domain is a geographical bounding box of latitude and longitude coordinates. 3. The eddy detector device of claim 1 , wherein determining the center of the eddy comprises determining a maximum sea surface height (SSH) observation within the base domain. 4. The eddy detector device of claim 1 , wherein determining the spatial criteria for finding edges of the eddy further comprises determining the spatial criteria based on the equation AP space = 1 + [ ( 0.1 ) * dADT ′ dr - d ⁢ ADT _ dr σ ⁡ ( dADT dr ) ] for each radial angle in the plurality of radial angles, where dADT ′ dR is the ADT gradient along a current angle in the plurality of radial angles, d ⁢ ADT _ dR is an average ADT gradient along all angles in the plurality of radial angles, and σ represents standard deviation. 5. The eddy detector device of claim 1 , wherein determining the temporal criteria for finding edges of the eddy comprises determining a ratio between a current ADT value and an initial ADT value for each radial angle in the plurality of radial angles around the circle centered at the center of the eddy. 6. The eddy detector device of claim 1 , wherein determining the potential edge points of the eddy comprises generating a plurality of edges from the center of the eddy at the plurality of radial angles around the circle centered at the center of the eddy. 7. The eddy detector device of claim 6 , wherein the radius of each edge in the plurality of edges is based on the spatial criteria and the temporal criteria. 8. The eddy detector device of claim 1 , wherein the eddy detector device is further configured to aid a sonar device or navigation device using the generated polygon. 9. A system for detecting an eddy, the system comprising: a satellite configured to gather climatological data; and an eddy detector device, the eddy detector device comprising a processing device and a memory coupled to the processing device, the memory containing executable instructions, wherein execution of the executable instructions, by the processing device, causes the processing device to perform operations comprising: receiving, using the processing device, the climatological data from the satellite, determining, using the processing device, a base domain for detecting the eddy, determining, using the processing device, a center of the eddy within the base domain, wherein determining the center of the eddy comprises determining a maximum absolute dynamic topography (ADT) observation within the base domain, determining, using the processing device, spatial criteria for finding edges of the eddy, wherein determining the spatial criteria for finding edges of the eddy comprises determining a plurality of outward ADT gradients from the center of the eddy in a plurality of directions, wherein the plurality of directions correspond to a plurality of radial angles around a circle centered at the center of the eddy, determining, using the processing device, temporal criteria for finding edges of the eddy, determining, using the processing device, potential edge points of the eddy based on the spatial criteria and the temporal criteria, and generating, using the processing device, a polygon around the potential edge points. 10. The system of claim 9 , wherein determining the temporal criteria for finding edges of the eddy comprises determining a ratio between a current ADT value and an initial ADT value for each radial angle in the plurality of radial angles around the circle centered at the center of the eddy. 11. The system of claim 9 , wherein determining the potential edge points of the eddy comprises generating a plurality of edges from the center of the eddy at the plurality of radial angles around the circle centered at the center of the eddy. 12. A method for detecting an eddy, the method comprising: receiving, using a processing device, climatological data; determining, using the processing device, a base domain for detecting the eddy; determining, using the processing device, a center of the eddy within the base domain, wherein determining the center of the eddy comprises determining a maximum absolute dynamic topography (ADT) observation within the base domain; determining, using the processing device, spatial criteria for finding edges of the eddy, wherein determini