Variable rate irrigation using motion sensor

The invention claimed is: 1. A sprinkler controller cooperable with a sprinkler assembly that receives fluid input from a pipe span, the sprinkler controller comprising: a microcontroller circuit; a motion sensor coupled with the microcontroller circuit; and a valve assembly including a modulator coupled with the microcontroller circuit and a valve coupled with the sprinkler assembly, wherein the valve meters or controls an amount of fluid output from the sprinkler assembly, wherein the microcontroller circuit is programmed to control the valve assembly based on input from the motion sensor such that the sprinkler assembly is configured via the microcontroller circuit to measure the sprinkler assembly's motion and calculate appropriate parameters to drive the modulator and the valve assembly to operate the valve so that the amount of fluid output is a function of the measured motion relative to a corresponding measured motion of at least one of an adjacent sprinkler assembly. 2. A sprinkler controller according to claim 1 , wherein the motion sensor is an accelerometer. 3. A sprinkler controller according to claim 1 , wherein the motion sensor is an inertial measurement device. 4. A sprinkler controller according to claim 1 , wherein the input from the motion sensor includes motion history. 5. A center pivot irrigation system comprising: a pivot center; a pipe span pivotally connected to the pivot center; a plurality of sprinkler assemblies connected along the pipe span; at least one movable pivot tower spaced from the pivot center and supporting the pipe span; and a sprinkler controller cooperable with each of the sprinkler assemblies, each of the sprinkler controllers including: a microcontroller circuit, a motion sensor coupled with the microcontroller circuit, and a valve assembly including a modulator coupled with the microcontroller circuit and a valve coupled with the sprinkler assembly, wherein the valve meters fluid output from the sprinkler assembly, wherein the microcontroller circuit is programmed to control the valve assembly based on a calculated value derived from input from the motion sensor such that the sprinkler assembly is configured via the microcontroller circuit to measure the sprinkler assembly's motion and calculate appropriate parameters to drive the modulator and the valve assembly to operate the valve so that the amount of fluid output is a function of the measured motion relative to a corresponding measured motion of at least one other sprinkler assembly of the plurality of sprinkler assemblies. 6. A center pivot irrigation system according to claim 5 , further comprising a primary controller circuit communicating with each of the sprinkler controllers, the primary controller circuit receiving motion sensor data from each of the microcontroller circuits, wherein the primary controller circuit is programmed to process the motion sensor data and assign a drop number to each microcontroller circuit based on a mathematical model. 7. A center pivot irrigation system according to claim 5 , wherein the sprinkler controllers are each programmed to share the input from the motion sensor with a neighboring sprinkler controller, and wherein the sprinkler controllers are programmed to compare the shared input with its own measured motion input to determine if the neighboring sprinkler controller is closer to or farther from the pivot center. 8. A center pivot irrigation system according to claim 7 , further comprising a primary controller circuit communicating with each of the sprinkler controllers, the primary controller circuit being programmed to determine a drop number for each of the sprinkler assemblies based on the shared input comparison by the sprinkler controllers. 9. A sprinkler controller set including a plurality of sprinkler controllers cooperable with a respective plurality of sprinkler assemblies that receive fluid input from a pipe span, the sprinkler controller set comprising a primary controller circuit communicating with each of the sprinkler controllers, wherein each of the sprinkler controllers in the sprinkler controller set comprises: a microcontroller circuit, and a motion sensor coupled with the microcontroller circuit, wherein the primary controller circuit is configured to receive motion sensor data from each of the microcontroller circuits, wherein the primary controller is programmed to process the motion sensor data and assign a drop number to each microcontroller circuit based on a mathematical model. 10. A sprinkler controller set according to claim 9 , wherein the motion sensor comprises an accelerometer. 11. A sprinkler controller set according to claim 10 , wherein the primary controller circuit is configured to compare a measured acceleration from each of the sprinkler controllers via the accelerometer such that the drop number for each of the microcontroller circuits can be assigned. 12. A sprinkler controller set according to claim 10 , wherein the primary controller circuit is configured to calculate a velocity of each of the sprinkler assemblies by integrating measured acceleration values from each of the sprinkler controllers, wherein relative velocities of each of the sprinkler assemblies yields the drop number for each of the microcontroller circuits. 13. A sprinkler controller set according to claim 9 , wherein each of the sprinkler controllers comprises a reed switch to enable a data reset. 14. A sprinkler controller set including a plurality of sprinkler controllers cooperable with a respective plurality of sprinkler assemblies that receive fluid input from a pipe span, each of the sprinkler controllers in the sprinkler controller set comprising: a microcontroller circuit, and a motion sensor coupled with the microcontroller circuit, wherein the sprinkler controllers are each programmed to share input from the motion sensor with a neighboring sprinkler controller, and wherein the sprinkler controllers are programmed to compare the shared input with the sprinkler controller's own measured motion input to determine if the neighboring sprinkler controller is closer to or farther from a pivot center. 15. A sprinkler controller set according to claim 14 , wherein each of the sprinkler controllers further comprises a valve assembly including a modulator coupled with the microcontroller circuit and a valve coupled with the sprinkler assembly, wherein the valve meters or controls an amount of fluid output from the sprinkler assembly, and wherein the microcontroller circuit is programmed to control the valve assembly based on input from the motion sensor such that the sprinkler assembly is configured via the microcontroller circuit to measure the sprinkler assembly's motion and calculate appropriate parameters to drive the modulator and the valve assembly to operate the valve so that the amount of fluid output is a function of the measured motion. 16. A sprinkler controller set according to claim 15 , wherein each of the sprinkler controllers further comprises an upstream pressure sensor and a downstream pressure sensor in fluid communication with the valve and coupled with the microcontroller circuit, the upstream pressure sensor measuring an upstream pressure value of the fluid input to the valve, and the downstream pressure sensor measuring a downstream pressure of the fluid exiting the valve, wherein the microcontroller circuit is configured to determine characteristics of fluid flow based on output from the upstream and downstream pressure sensors. 17. A sprinkler controller set according to claim 15 , where