System and method for monitoring shank float

The invention claimed is: 1. A shank assembly for an agricultural tillage implement comprising a frame, comprising: a support arm comprising a first end and a second end, the first end being configured for pivotally connecting to the frame; a shank comprising a first end and a second end, the first end of the shank being connected to the second end of the support arm; a point connected to the second end of the shank and configured for engaging with soil; and a float monitoring system, comprising: a first sensor configured for being connected to the frame and sensing a home position; a second sensor connected to the support arm and configured for sensing an angular position of the support arm relative to the frame; and an electronic control unit operably connected to the first sensor and the second sensor and configured for comparing the home position and the angular position of the support arm and determining a float of the shank as the shank is towed in a forward direction of travel; and wherein the second end of the support arm comprises a bracket which mounts the shank to the support arm, and the second sensor is mounted on the bracket of the support arm, and wherein the shank assembly further comprises a spring mounting bracket connected to the bracket of the support arm at a first location by at least one fastener and a spring connected to the spring mounting bracket. 2. The shank assembly of claim 1 , wherein the electronic control unit is configured for determining the float of the shank by extrapolating a depth of the shank from the angular position of the support arm relative to the home position. 3. The shank assembly of claim 1 , wherein the first sensor and the second sensor are respectively in the form of a first inclinometer sensor and a second inclinometer sensor. 4. The shank assembly of claim 3 , wherein the first inclinometer sensor and the second inclinometer sensor are each in the form of an electronic inclinometer sensor. 5. The shank assembly of claim 1 , further comprising a plate connected to the bracket of the support arm at the first location by the at least one fastener which connects the spring mounting bracket to the bracket of the support arm, and wherein the second sensor is mounted onto the plate such that the plate mounts the second sensor onto the bracket of the support arm. 6. The shank assembly of claim 1 , wherein the electronic control unit is further configured for alerting an operator of the agricultural tillage implement of the float of the shank. 7. An agricultural tillage implement for an agricultural vehicle, comprising: a frame; at least one shank assembly connected to the frame, each shank assembly comprising: a support arm comprising a first end and a second end, the first end being pivotally connected to the frame; a shank comprising a first end and a second end, the first end of the shank being connected to the second end of the support arm; and a point connected to the second end of the shank and configured for engaging with soil; and a float monitoring system, comprising: a first sensor connected to the frame and configured for sensing a home position; a second sensor connected to the support arm of the at least one shank assembly and configured for sensing an angular position of the support arm relative to the frame; and an electronic control unit operably connected to the first sensor and the second sensor and configured for comparing the home position and the angular position of the support arm and determining a float of the shank as the shank is towed in a forward direction of travel; and wherein the second end of the support arm comprises a bracket which mounts the shank to the support arm, and the second sensor is mounted on the bracket of the support arm, and wherein the agriculture tillage implement further comprises a spring mounting bracket connected to the bracket of the support arm at a first location by at least one fastener and a spring connected to the spring mounting bracket. 8. The agricultural tillage implement of claim 7 , wherein the electronic control unit is configured for determining the float of the shank by extrapolating a depth of the shank from the angular position of the support arm relative to the home position. 9. The agricultural tillage implement of claim 7 , wherein the first sensor and the second sensor are respectively in the form of a first inclinometer sensor and a second inclinometer sensor. 10. The agricultural tillage implement of claim 9 , wherein the first inclinometer sensor and the second inclinometer sensor are each in the form of an electronic inclinometer sensor. 11. The agricultural tillage implement of claim 7 , further comprising a plate connected to the bracket of the support arm at the first location by the at least one fastener which connects the spring mounting bracket to the bracket of the support arm, and wherein the second sensor is mounted onto the plate such that the plate mounts the second sensor onto the bracket of the support arm. 12. The agricultural tillage implement of claim 7 , wherein the electronic control unit is further configured for alerting an operator of the agricultural tillage implement of the float of the shank. 13. The agricultural tillage implement of claim 7 , wherein the at least one shank assembly comprises a plurality of shank assemblies respectively mounted to the frame, and the float monitoring system comprises a respective second sensor connected to each support arm of the plurality of shank assemblies. 14. A method of operating an agricultural tillage implement comprising a frame, comprising: providing a shank assembly for the agricultural tillage implement, the shank assembly comprising a support arm comprising a first end and a second end, the first end being configured for pivotally connecting to the frame, a shank comprising a first end and a second end, the first end of the shank being connected to the second end of the support arm, a point connected to the second end of the shank and configured for engaging with soil, and a float monitoring system, the float monitoring system comprising a first sensor configured for being connected to the frame, a second sensor connected to the support arm, and an electronic control unit operably connected to the first sensor and the second sensor; wherein the second end of the support arm comprises a bracket for mounting the shank to the support arm, and the second sensor is mounted on the bracket of the support arm, and wherein the agriculture tillage implement further comprises a spring mounting bracket connected to the bracket of the support arm at a first location by at least one fastener and a spring connected to the spring mounting bracket, sensing, by the first sensor, a home position of the frame; sensing, by the second sensor, an angular position of the support arm relative to the frame; comparing, by the electronic control unit, the home position and the angular position of the support arm; and determining, by the electronic control unit, a float of the shank as the shank is towed in a forward direction of travel. 15. The method of claim 14 , wherein the step of determining the float of the shank comprises extrapolating, by the electronic control unit, a depth of the shank from the angular position of the support arm relative to the home position. 16. The method of claim 14 , further comprising a step of alerting, by the electronic control unit, an operator of the agricultural tillage implement of the float of the shank.