An agricultural trench depth sensing system having a trench implement adapted to be disposed in a soil trench opened in a soil surface. In one embodiment an ultrasonic sensor detects a distance to an upper surface of said trench implement or a target disposed thereon. In another embodiment, said trench implement includes one or more fingers which rotate with respect to said trench implement to detect the soil surface relative to said trench implement. In another embodiment, said trench implement includes side sensors for detecting the sidewall of the soil trench.

An agricultural trench depth sensing system having a trench implement adapted to be disposed in a soil trench opened in a soil surface. In one embodiment an ultrasonic sensor detects a distance to an upper surface of said trench implement or a target disposed thereon. In another embodiment, said trench implement includes one or more fingers which rotate with respect to said trench implement to detect the soil surface relative to said trench implement. In another embodiment, said trench implement includes side sensors for detecting the sidewall of the soil trench.

An agricultural trench depth sensing system having a trench implement adapted to be disposed in a soil trench opened in a soil surface. In one embodiment an ultrasonic sensor detects a distance to an upper surface of said trench implement or a target disposed thereon. In another embodiment, said trench implement includes one or more fingers which rotate with respect to said trench implement to detect the soil surface relative to said trench implement. In another embodiment, said trench implement includes side sensors for detecting the sidewall of the soil trench.

An agricultural trench depth sensing system having a trench implement adapted to be disposed in a soil trench opened in a soil surface. In one embodiment an ultrasonic sensor detects a distance to an upper surface of said trench implement or a target disposed thereon. In another embodiment, said trench implement includes one or more fingers which rotate with respect to said trench implement to detect the soil surface relative to said trench implement. In another embodiment, said trench implement includes side sensors for detecting the sidewall of the soil trench.

A method for calculating a magnetic influence factor (MIF) between an atom and a resonant atom of a molecule of a material includes determining a current magnetic field strength at a test location above a quantity of material buried at the test location, transmitting a test signal from an antenna at the test location, the test signal comprising a test fundamental frequency, and detecting, at the test location, a reflected wave comprising the test fundamental frequency on the antenna. The method includes varying the test fundamental frequency while retransmitting the test signal and detecting a reflected wave until reflected waves of various test frequencies are detected and identifying from the detected reflected waves a resonant frequency corresponding to a maximum magnitude of the detected reflected waves. The material includes molecules with a resonant atom and at least one atom different than the resonant atom.

A method for calculating a magnetic influence factor (MIF) between an atom and a resonant atom of a molecule of a material includes determining a current magnetic field strength at a test location above a quantity of material buried at the test location, transmitting a test signal from an antenna at the test location, the test signal comprising a test fundamental frequency, and detecting, at the test location, a reflected wave comprising the test fundamental frequency on the antenna. The method includes varying the test fundamental frequency while retransmitting the test signal and detecting a reflected wave until reflected waves of various test frequencies are detected and identifying from the detected reflected waves a resonant frequency corresponding to a maximum magnitude of the detected reflected waves. The material includes molecules with a resonant atom and at least one atom different than the resonant atom.

A planting system having a plurality of row units, each row unit having: (a) at least one opening disc configured to open a seed trench; (b) a soil engaging member configured to engage a sidewall of the trench during planting; and (c) at least one strain gauge in operative communication with the soil engaging member, wherein the at least one strain gauge measures force on the soil engaging member during planting operations.

A planting system having a plurality of row units, each row unit having: (a) at least one opening disc configured to open a seed trench; (b) a soil engaging member configured to engage a sidewall of the trench during planting; and (c) at least one strain gauge in operative communication with the soil engaging member, wherein the at least one strain gauge measures force on the soil engaging member during planting operations.

A row planting unit closing system including a first stage closing unit adapted to be attached to a row planting unit and including: a first stage frame; and a set of at least one row closing wheel having a closing angle orientation non-perpendicular relative to the ground; and wherein the first stage frame is attached at a first end to the row planting unit, the first stage frame comprising a linkage mechanism for setting a toe in angle orientation of the set of at least one row closing wheel relative to the first stage frame.

A row planting unit closing system including a first stage closing unit adapted to be attached to a row planting unit and including: a first stage frame; and a set of at least one row closing wheel having a closing angle orientation non-perpendicular relative to the ground; and wherein the first stage frame is attached at a first end to the row planting unit, the first stage frame comprising a linkage mechanism for setting a toe in angle orientation of the set of at least one row closing wheel relative to the first stage frame.