System for automatically setting the set point of a planter automatic down pressure control system with a seed furrow sidewall compaction measurement device

The invention claimed is: 1. An agricultural row unit for planting seeds in a furrow, comprising a frame having (a) a gauge wheel that engages the soil to control the elevation of the frame and (b) an opening tool that cuts a furrow in the soil to be planted, a gauge wheel down force control system that includes an actuator applying a controllable down pressure to said gauge wheel to control the depth of said furrow, a monitoring device extending into the furrow and into the sidewalls of the furrow and producing a signal representing the compaction of the soil in said sidewalls, wherein a width of said monitoring device is slightly bigger than a width of said furrow so that said monitoring device simultaneously penetrates into both of said sidewalls of said furrow on opposite sides thereof, and a controller supplying said actuator with a control signal representing a down pressure set point to form a furrow having a desired depth, said controller receiving said signal representing the compaction of the soil in said sidewalls and using said signal in an algorithm to determine whether said down pressure set point should be increased or decreased, and supplying said actuator with a control signal when it is determined that said down pressure set point should be increased or decreased. 2. The agricultural row unit of claim 1 in which said side-monitoring device includes lateral projections that extend into the sidewalls of the furrow, and a load cell coupled to said projections to produce an electrical signal that changes with the compaction of the soil in the furrow sidewalls. 3. The agricultural row unit of claim 2 in which said projections are wings that extend laterally across the furrow from opposite sides of a bar that is dragged along the furrow, the tips of said wings extending into both of the furrow side walls. 4. The agricultural row unit of claim 2 which includes a controller that receives said electrical signal and produces said control signal based at least in part on said electrical signal from said load cell. 5. A method of controlling the down pressure on an agricultural row unit for planting seeds in a furrow and including a gauge wheel down force control system that includes an actuator applying a controllable down pressure to the gauge wheel to control the depth of the furrow, said method comprising supplying said actuator with a control signal representing a down pressure set point, sensing, from a monitoring device, the compaction of the soil forming the sidewalls of the furrow and producing a signal representing the sensed compaction, wherein a width of said monitoring device is slightly wider than a width of said furrow so that said monitoring device simultaneously penetrates into both of said sidewalls of the furrow on opposite sides thereof, using said signal representing the sensed compaction in an algorithm to determine whether said down pressure set point should be increased or decreased, and adjusting said control signal representing a down pressure set point when it is determined that said down pressure set point should be increased or decreased. 6. The method of claim 5 in which said monitoring device includes lateral projections that extend into the sidewalls of the furrow, and a load cell coupled to said projections and producing an electrical signal that changes with the compaction of the soil in the furrow sidewalls. 7. The method of claim 6 in which said projections are wings that extend laterally across the furrow from opposite sides of a bar that is dragged along the furrow, the tips of said wings extending into both sides of the furrow side walls. 8. The method of claim 6 in which a controller receives said electrical signal and produces said control signal based at least in part on said electrical signal from said load cell. 9. The agricultural row unit of claim 3 , wherein movement of the agricultural row unit through said furrow pushes said wings towards each other, wherein said wings apply opposite forces onto said load cell, wherein said load cell produces an output signal having a magnitude proportional to the opposite forces. 10. The method of claim 7 , wherein producing the signal representing the sensed compaction further comprises: receiving opposite forces on said load cells from said wings, wherein the opposite forces comprises applied pressure from said wings when the agricultural row unit moves through said furrow, and producing an output signal having a magnitude proportional to the opposite forces. 11. An agricultural row unit for planting seeds in a furrow, comprising a frame having (a) a gauge wheel that engages the soil to control the elevation of the frame and (b) an opening tool that cuts a furrow in the soil to be planted, a gauge wheel down force control system that includes an actuator applying a controllable down pressure to said gauge wheel to control the depth of said furrow, a sidewall compaction measuring device extending into the furrow and into the sidewalls of the furrow and producing a signal representing the compaction of the soil in said sidewalls, wherein a width of said sidewall compaction measuring device is slightly bigger than a width of said furrow so that said measuring device simultaneously penetrates into both of the sidewalls of the furrow on opposite sides thereof, and a controller supplying said actuator with a control signal representing a down pressure set point to form a furrow having a desired depth, said controller receiving said signal representing the compaction of the soil in said sidewalls and using said signal in an algorithm to determine whether said down pressure set point should be increased or decreased, and supplying said actuator with a control signal when it is determined that said down pressure set point should be increased or decreased. 12. The agricultural row unit of claim 11 , in which said sidewall compaction measuring device includes lateral projections that extend laterally across the furrow into both of the sidewalls of the furrow, the lateral projections being urged towards each other as the agricultural row unit traverses said furrow, such that an extent that the lateral projections are urged towards each other is indicative of an extent of the compaction of the soil. 13. The agricultural row unit of claim 1 in which said monitoring device includes a passageway to permit fertilizer to pass through said monitoring device and into said furrow. 14. The method of claim 5 further comprising passing a fertilizer via a passageway in said monitoring device through said monitoring device into said furrow. 15. The agricultural row unit of claim 11 in which said measuring device includes a passageway to permit fertilizer to pass through said monitoring device and into said furrow.