System and method for determining seed placement during a seed-planting operation

The invention claimed is: 1 . A seed-planting implement, comprising: a frame; a disk opener rotatably coupled to the frame; a gauge wheel adjustably coupled to the frame; first and second radar sensors supported on the frame; a computing system communicatively coupled to the first and second radar sensors, the computing system configured to: control the first radar sensor such that the first radar sensor scans a sub-surface detection zone of a field before a seed is deposited within the sub-surface detection zone; receive first radar sensor data including a plurality of first radar data points from the first radar sensor, each first radar data point corresponding to a parameter associated with a reflection of an output signal emitted by the first radar sensor from a given location within the sub-surface detection zone; populate a first matrix including a plurality of cells with the plurality of first data points such that each first data point is placed within a cell corresponding to the given location within the sub-surface detection zone; after controlling the first radar sensor, control the second radar sensor such that the second radar sensor scans the sub-surface detection zone of the field after the seed is deposited within the sub-surface detection zone; receive second radar sensor data including a plurality of second radar data points from the second radar sensor, each second radar data point corresponding to a parameter associated with a reflection of an output signal emitted by the second radar sensor from a given location within the sub-surface detection zone; populate a second matrix including a plurality of cells with the plurality of second data points such that each second data point is placed within a cell corresponding to the given location within the sub-surface detection zone; and determine a location of the seed based on the first and second matrices. 2 . The seed-planting implement of claim 1 , wherein the computing system is configured to control an operation of the seed-planting implement based on the determined location of the seed. 3 . The seed-planting implement of claim 1 , wherein the sub-surface detection zone comprises a two-dimensional plane extending in a longitudinal direction that is parallel to a direction of travel of the seed-planting implement and a vertical direction that is perpendicular to the longitudinal direction. 4 . The seed-planting implement of claim 3 , wherein: when controlling the first radar sensor, the computing system is configured to control the first radar sensor such that the first radar sensor performs a one-dimensional scan of a portion of the sub-surface detection zone extending in the vertical direction before the seed is deposited within the soil of the field; and when controlling the second radar sensor, the computing system is configured to control the second radar sensor such that the second radar sensor performs a one-dimensional scan of the portion of the sub-surface detection zone extending in the vertical direction after the seed is deposited within the soil of the field. 5 . The seed-planting implement of claim 4 , wherein: when populating the first matrix, the computing system is configured to populate a column of the plurality of cells of the first matrix with the plurality of first data points received from the one-dimensional scan of the portion of the sub-surface detection zone by the first radar sensor; and when populating the second matrix, the computing system is configured to populate a column of the plurality of cells of the second matrix with the plurality of second data points received from the one-dimensional scan of the portion of the sub-surface detection zone by the second radar sensor. 6 . A system for determining seed placement during a seed-planting operation, the system comprising: first and second radar sensors; a computing system communicatively coupled to the first and second radar sensors, the computing system configured to: control the first radar sensor such that the first radar sensor scans a sub-surface detection zone of a field before a seed is deposited within the sub-surface detection zone; receive first radar sensor data including a plurality of first radar data points from the first radar sensor, each first radar data point corresponding to a parameter associated with a reflection of an output signal emitted by the first radar sensor from a given location within the sub-surface detection zone; populate a first matrix including a plurality of cells with the plurality of first data points such that each first data point is placed within a cell corresponding to the given location within the sub-surface detection zone; after controlling the first radar sensor, control the second radar sensor such that the second radar sensor scans the sub-surface detection zone of the field after the seed is deposited within the sub-surface detection zone; receive second radar sensor data including a plurality of second radar data points from the second radar sensor, each second radar data point corresponding to a parameter associated with a reflection of an output signal emitted by the second radar sensor from a given location within the sub-surface detection zone; populate a second matrix including a plurality of cells with the plurality of second data points such that each second data point is placed within a cell corresponding to the given location within the sub-surface detection zone; and determine a location of the seed based on the first and second matrices. 7 . The system of claim 6 , wherein, when determining the location of the seed, the computing system is configured to compare the first and second matrices to determine the location of the seed. 8 . The system of claim 6 , wherein the location of the seed comprises a depth of the seed below a surface of the field. 9 . The system of claim 6 , further comprising: an auxiliary sensor communicatively coupled to the computing system, the auxiliary sensor configured to generate data indicative of a relative positioning of the first and second radar sensors, wherein, when controlling the second radar sensor, the computing system is configured to control the second radar sensor based on the data generated by the auxiliary sensor. 10 . The system of claim 6 , wherein the parameter associated with the reflection of the output signal emitted by the first radar sensor and the parameter associated with the reflection of the output signal emitted by the second radar sensor are indicative of a phase of the reflections. 11 . The system of claim 6 , wherein the parameter associated with the reflection of the output signal emitted by the first radar sensor and the parameter associated with the reflection of the output signal emitted by the second radar sensor are indicative of a magnitude of the reflections. 12 . The system of claim 6 , wherein the parameter associated with the reflection of the output signal emitted by the first radar sensor and the parameter associated with the reflection of the output signal emitted by the second radar sensor are indicative of a time domain of the reflections. 13 . The system of claim 6 , wherein the computing system is configured to control an operation of the seed-planting implement based on the determined location of the seed. 14 . The system of claim 6 , wherein the sub-surface detection zone comprises a two-dimensional plane extending in a longitudinal direction that is parallel to a direction of travel of the seed-planting implement and a vertical direction that is perpendicular to the longitudinal direction.