초록 ▼

A method of using an unmanned agricultural robot to generate an anticipatory geospatial data map of the positions of annual crop rows planted within a perimeter of an agricultural field, the method including the step of creating a geospatial data map of an agricultural field by plotting actual annua

A method of using an unmanned agricultural robot to generate an anticipatory geospatial data map of the positions of annual crop rows planted within a perimeter of an agricultural field, the method including the step of creating a geospatial data map of an agricultural field by plotting actual annual crop row positions in a portion of the geospatial data map that corresponds to a starting point observation window, and filling in a remainder of the geospatial data map with anticipated annual crop row positions corresponding to the annual crop rows outside of the starting point observation window, and refining the geospatial data map by replacing the anticipated annual crop row positions with measured actual annual crop row positions when an unexpected obstacle is encountered.

대표청구항 ▼

1. A method of using an unmanned agricultural robot to generate an anticipatory geospatial data map of positions of annual crop rows planted within a perimeter of an agricultural field, the method comprising: delivering the unmanned agricultural robot to the agricultural field, wherein the unmanned

1. A method of using an unmanned agricultural robot to generate an anticipatory geospatial data map of positions of annual crop rows planted within a perimeter of an agricultural field, the method comprising: delivering the unmanned agricultural robot to the agricultural field, wherein the unmanned agricultural robot is programmed with a self-direction program;positioning the unmanned agricultural robot at a starting point on the agricultural field;deploying one or more aerial mapping sensors at a height above the agricultural field, so as to enable the one or more aerial mapping sensors to capture geospatial data within an observation window of the agricultural field, the observation window dimensioned such that a width and length of the observation window are at least three times a nominal width of the annual crop rows;using the one or more aerial mapping sensors to measure the actual annual crop row positions within the starting point observation window relative to at least one of the unmanned agricultural robot and the perimeter of the agricultural field;creating the geospatial data map of the entire agricultural field by plotting the actual annual crop row positions in a portion of the geospatial data map that corresponds to the starting point observation window, and filling in a remainder of the geospatial data map with anticipated annual crop row positions corresponding to the annual crop rows outside of the starting point observation window, wherein the measured actual annual crop row positions are used to predict the anticipated annual crop row positions within the perimeter of the agricultural field;activating the self-direction program to autonomously navigate the unmanned agricultural robot within the perimeter of the agricultural field; andusing the one or more aerial mapping sensors to periodically refine the geospatial data map by replacing the anticipated annual crop row positions with measured actual annual crop row positions within the observation window when an unexpected obstacle is encountered during autonomous navigation.