Seeding control system and method

The invention claimed is: 1. A method of maintaining a desired seed population rate of a row unit of an agricultural planter during periods of acceleration of the agricultural planter while planting a field, wherein the row unit includes a seed meter, a variable rate drive and a seed sensor, the seed meter configured to dispense singulated seeds by rotation of a seed disc, the variable rate drive driving rotation of the seed disc, the seed sensor configured to generate a seed pulse upon the dispensed singulated seeds passing the seed sensor, said method comprising: (a) communicating inputted criteria entered via a planter monitor to a control unit, the control unit controlling the variable rate drive, the inputted criteria including a desired seed population rate, a number of seed entraining features on the seed disc, a diameter of the seed entraining features on the seed disc, and a preferred planter ground speed; (b) the control unit determining the rotational speed of the seed disc based on sensed revolutions of the variable rate drive; (c) via signals generated by a GPS system, determining a GPS-reported ground speed of the agricultural planter; (d) via signals generated by a radar system, determining a radar-reported ground speed of the agricultural planter; (e) identifying a highest stable ground speed and a lowest stable ground speed from the GPS-reported ground speed and the radar-reported ground speed; (f) via signals generated by a horizontal accelerometer, determining horizontal acceleration of the agricultural planter; (g) if the measured horizontal acceleration is greater than a predefined upper acceleration threshold, the control unit generating a signal to cause the variable rate drive to drive the seed disc at a rotational speed to maintain the desired seed population rate based on the determined highest stable ground speed; (h) if the measured horizontal acceleration is less than a predefined lower acceleration threshold, the control unit generating a signal to cause the variable rate drive to drive the seed disc at a rotational speed to maintain the desired seed population rate based on the determined lowest stable ground speed; and (i) if the measured horizontal acceleration is less than the predefined upper acceleration threshold and is greater than the predefined lower acceleration threshold, the control unit generating a signal to cause the variable rate drive to drive the seed disc at a rotational speed to maintain the desired seed population rate based on the inputted preferred planter ground speed. 2. The method of claim 1 , further comprising a method of estimating stopping times of the planter in order to stop rotation of the seed disc driven by the variable rate drive in order to minimize over planting and under planting, the method comprising: via signals generated by the horizontal accelerometer, determining when the agricultural planter is decelerating and calculating a deceleration rate; if the planter ground speed falls below a predetermined low planter speed threshold, calculating a stopping time of the agricultural planter based on the calculated deceleration rate; upon the calculated stopping time of the planter equaling a predetermined stop delay associated with the variable rate drive, the control unit generating a signal to cause the variable rate drive to stop driving the seed disc. 3. The method of claim 2 , further comprising a method of resuming driving of the seed disc by the variable rate drive from a stopped condition in order to minimize over planting and under planting, the method comprising: via signals generated by the horizontal accelerometer, determining when the planter has resumed a forward direction of travel from a stationary position; integrating the signals generated by the horizontal accelerometer to determine when the ground speed of the agricultural planter reaches a minimum planter speed threshold; upon the ground speed of the planter achieving the minimum planter speed threshold, the control unit generating a signal to cause the variable rate drive to start driving the seed disc. 4. The method of claim 1 , wherein the predefined upper acceleration threshold is about 1.5 ft/s 2 . 5. The method of claim 1 , wherein the predefined lower acceleration threshold is about −1.5 ft/s 2 . 6. The method of claim 2 , wherein the predetermined low planter speed threshold is about 4.5 ft/s. 7. The method of claim 2 , wherein the stop delay is determined by generating a stop signal, via the control unit, to cause the variable rate drive to stop driving rotation of the seed disc of the row unit; measuring a time difference between a time when the stop signal is generated until a last seed pulse is thereafter generated by the seed sensor of the row unit; storing in memory the measured time difference as the stop delay. 8. The method of claim 1 , further comprising a method of determining a start delay: via the control unit, generating a start signal to cause the variable rate drive to start driving rotation of the seed disc of the row unit; measuring a time difference between a time when the start signal is generated until a first seed pulse is thereafter generated by the seed sensor of the row unit; storing in memory the measured time difference as the start delay. 9. The method of claim 8 , further comprising: generating an alert if no seed pulse is generated by the seed sensor of the row unit within a predetermined time after generating the start signal. 10. The method of claim 1 , further comprising: via the GPS system, identifying a seed placement location in the field of each generated seed pulse; and storing in memory each seed placement location. 11. The method of claim 10 , further comprising: generating a seed placement map of each seed placement location within the field. 12. The method of claim 10 , wherein the agricultural planter includes a plurality of the row units arranged in a plurality of swaths, wherein each swath includes at least one of the row units, each swath further including a swath controller in signal communication with the control unit and the variable rate drive of each of the at least one row units comprising each swath. 13. The method of claim 12 , wherein each swath comprises one row unit such that the swath controller provides one-row swath control. 14. The method of claim 12 , wherein each swath comprises multiple row units such that the swath controller provides multi-row swath control. 15. The method of claim 1 , wherein the inputted criteria includes a desired coverage pattern with respect to a stop planting boundary, the coverage pattern selected from a group comprising: underplanting the stop-planting boundary, overplanting the stop-planting boundary, and 50/50-overplanting/underplanting of the stop-planting boundary, the stop planting boundary including any previously stored seed placement location, a previously determined field outer boundary, and a previously determined field inner boundary. 16. The method of claim 15 , further comprising: via the control unit, actuating the swath controller to operably disengage the variable rate drive to stop rotation of the seed disc of the at least one of the row units comprising the swath crossing the stop-planting boundary.