Autonomous method for detecting a pile

What is claimed is: 1. An autonomous method for detecting when an earthmoving machine has moved a pile of dirt into contact with another pile of dirt, the method comprising: receiving at a controller a plurality of signals indicative of one or more parameters including a ground speed of the machine, a target ground speed of the machine, a load on a work implement of the machine, an output speed of a torque converter of the machine, a machine pitch, a machine steering command, a machine heading, and a heading of a slot the machine is in; standardizing and normalizing each signal from the plurality of signals using the controller in order to create values for each of the one or more parameters that all fall within a common range, wherein the common range is representative of a range from minimum to maximum values for each of the one or more parameters; determining, using the controller, a variation of each of the values for the one or more parameters over each of a plurality of time periods to calculate relative rates of change for the one or more parameters; weighting each of the values for each of the one or more parameters as a function of the relative rates of change for the one or more parameters; adding up the weighted values of the parameters; applying a sigmoid function to the weighted values of the parameters using the controller in order to limit the effect any one of the parameters has on an output indicative of behavior characteristic of the machine having pushed a pile of dirt into contact with another pile of dirt; and transitioning a work implement of the machine from a carry configuration to a spread configuration. 2. The autonomous method of claim 1 , further including weighting the weighted values of each of the one or more parameters in relationship to each of the other weighted values of other parameters based on which of the parameters predominates in exhibiting behavior of the machine characteristic of the machine having pushed a pile of dirt into contact with another pile of dirt. 3. The autonomous method of claim 1 , wherein transitioning the work implement to a carry configuration includes racking the work implement backwards in order to retain more material in the work implement, and transitioning the work implement to a spread configuration includes pitching the work implement forward in order to shed more material from the work implement. 4. The autonomous method of claim 1 , further including determining a configurable reverse time that is allowed to elapse between detection that the machine has pushed a pile of dirt into contact with another pile of dirt and when the machine is reversed. 5. The autonomous method of claim 4 , wherein a longer configurable reverse time corresponds to the machine compacting the material from the pile of dirt being pushed by the machine into another pile of dirt by a greater amount than when a shorter configurable reverse time is allowed to elapse. 6. The autonomous method of claim 5 , wherein a longer configurable reverse time corresponds to a smaller material load being carried by the machine and a shorter configurable reverse time corresponds to a larger material load being carried by the machine. 7. The autonomous method of claim 1 , wherein the common range is set from approximately −1000 to +1000, and wherein an upper threshold of the range corresponds to the machine pushing a pile of dirt into another pile of dirt, and a lower threshold of the range corresponds to the machine shedding material from a work implement of the machine. 8. The autonomous method of claim 1 , wherein the method steps only commence when the machine is within a predetermined distance from a last pile of dirt. 9. A system for autonomously controlling an earthmoving machine, wherein the earthmoving machine includes: a frame; a plurality of driving members connected to the frame and configured to support the frame; a powertrain mounted to the frame and configured to drive the plurality of driving members; a work implement operatively connected to the frame and having a surface configured to engage a material to be moved by the machine; and at least a first sensor configured to generate a first signal indicative of at least one of a plurality of operational parameters of the machine; the system further including a controller in communication with the at least a first sensor, controls for the powertrain, and controls for the work implement, the controller being configured to implement a method for operating the machine comprising: receiving a plurality of signals indicative of one or more parameters including a ground speed of the machine, a target ground speed of the machine, a load on the work implement of the machine, an output speed of a torque converter of the machine, a machine pitch, a machine steering command, a machine heading, and a heading of a slot the machine is in; standardizing and normalizing each signal from the plurality of signals in order to create values for each of the one or more parameters that all fall within a common range, wherein the common range is representative of a range from minimum to maximum values for each of the one or more parameters; determining a variation of each of the values for the one or more parameters over each of a plurality of time periods to calculate relative rates of change for the one or more parameters; weighting each of the values for each of the one or more parameters as a function of the relative rates of change for the one or more parameters; adding up the weighted values of the parameters; and applying a sigmoid function to the weighted values of the parameters in order to limit the effect any one of the parameters has on an output indicative of behavior characteristic of the machine having pushed a pile of dirt into contact with another pile of dirt. 10. The system of claim 9 , wherein the controller is further configured to weight the weighted values of each of the one or more parameters in relationship to each of the other weighted values of other parameters based on which of the parameters has the greatest effect on a determination that the machine has pushed a pile of dirt into another pile of dirt. 11. The system of claim 9 , wherein the controller is further configured to transition the work implement of the machine from a carry configuration to a spread configuration. 12. The system of claim 11 , wherein the controller is configured to transition the work implement to a carry configuration by racking the work implement backwards in order to retain more material in the work implement, and transition the work implement to a spread configuration by pitching the work implement forward in order to shed more material from the work implement. 13. The system of claim 9 , wherein the controller is further configured to determine a configurable reverse time that is allowed to elapse between detection that the machine has pushed a pile of dirt into contact with another pile of dirt and when the machine is reversed in a direction away from the pile of dirt. 14. The system of claim 13 , wherein a longer configurable reverse time corresponds to the machine compacting the material from the pile of dirt being pushed by the machine into another pile of dirt by a greater amount than when a shorter configurable reverse time is allowed to elapse. 15. The system of claim 14 , wherein a longer configurable reverse time corresponds to a smaller blade load being carried by the machine and a shorter configurable reverse time corresponds to a larger blade load being carried by the machine. 16. The system of claim