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"description": "A system (100) and a method (700) for estimating a position (510) of an object (170). The object (170) includes a gradiometer (110). The method (700) includes calculating a gravity vector (270) using a gravity spatial derivative (210) generated by the gradiometer (110) and a plurality of body…",
"path": "/patents/1386000",
"publishedAt": "2026-06-03T00:00:00.000Z",
"site": "at://did:plc:oql6ds5vnff4ugar6rruliwd/site.standard.publication/3mn3ohu7oxx5w",
"tags": [
"G01C21/005",
"GE AVIATION SYSTEMS LLC [US]"
],
"textContent": "A system (100) and a method (700) for estimating a position (510) of an object (170). The object (170) includes a gradiometer (110). The method (700) includes calculating a gravity vector (270) using a gravity spatial derivative (210) generated by the gradiometer (110) and a plurality of body velocities (220) generated by a body velocity source (120), calculating a gravity potential (430) based on the gravity vector (270), and estimating an inertial measurement unit (IMU)-based position (250) of the object (170) using the gravity vector (270), a body acceleration (230), and a body attitude (240). The IMU (130) generates the body acceleration (230) and the body attitude (240). The method (700) includes estimating a gravity vector-based position (310) of the object (170) using the gravity vector (270) and estimating a gravity map-based position (410) of the object (170) using the gravity potential (430) and one or more gravitational maps (440). The method (700) estimating a position (510) of the object (170) based on the IMU-based position (250), the gravity vector-based position (310), and the gravity map-based position (410). The method (700) includes outputting the position (510) of the object (170) to an output device (150).",
"title": "VEHICLE POSITION ESTIMATION SYSTEM"
}