Suspension control system providing closed loop control of hydraulic fluid volumes for an agricultural machine

What is claimed is: 1. A suspension system for an agricultural machine, comprising: a plurality of suspension assemblies, each suspension assembly comprising a swing frame assembly and a cylinder, each cylinder comprising a piston rod configured to extend and retract with respect to a base, wherein the swing frame assembly is coupled to the agricultural machine, and wherein the cylinder is operationally coupled to the swing frame assembly at an actuation point; a plurality of position sensors, each position sensor being configured to generate a signal indicating a suspension height; a plurality of electronically controlled valves, each electronically controlled valve being configured to control a flow of fluid to and from a control volume for operating a cylinder; a plurality of accumulators, each accumulator comprising a fluid portion moveable with respect to a gas portion, each accumulator being configured with respect to a cylinder, wherein each control volume for operating a cylinder includes a fluid portion of an accumulator; a plurality of pressure sensors, each pressure sensor being configured to generate a signal indicating a pressure of a control volume; and a processor in communication with the plurality of position sensors, the plurality of electronically controlled valves and the plurality of pressure sensors, the processor executing a program stored in a non-transient medium to: determine a measured amount of fluid in each control volume using a position indicated by a position sensor configured with respect to a cylinder and a pressure indicated by a pressure sensor of a control volume for the cylinder; calculate an error value for each control volume as a difference between a target amount of fluid for the control volume and the measured amount of fluid in the control volume; and control the electronically controlled valves in a closed loop control system to flow fluid to or from the control volume to minimize the error value. 2. The suspension system of claim 1 , wherein the electronically controlled valves are controlled in closed loop Proportional-Integral-Derivative (PID) control systems. 3. The suspension system of claim 1 , wherein each cylinder is a dual action hydraulic cylinder, and wherein the processor communicates with the plurality of position sensors, the plurality of electronically controlled valves and the plurality of pressure sensors through a vehicle bus. 4. The suspension system of claim 1 , wherein the measured amount of hydraulic fluid in each control volume is determined by adding a volume of the hydraulic cylinder having a portion of the control volume and a volume of the hydraulic fluid portion of an accumulator having another portion the control volume, wherein the volume of the hydraulic cylinder is determined from the position indicated by the position sensor and the volume of the hydraulic fluid portion of the accumulator is determined from the pressure indicated by a pressure sensor. 5. The suspension system of claim 4 , wherein the volume of the hydraulic fluid portion of the accumulator is determined by determining a volume of the gas portion of the accumulator using the ideal gas law and subtracting the volume of the gas portion of the accumulator from a total volume of the accumulator. 6. The suspension system of claim 1 , further comprising a plurality of temperature sensors, each temperature sensor being configured to generate a signal indicating a temperature of a control volume. 7. The suspension system of claim 6 , wherein the measured amount of hydraulic fluid in each control volume is determined by also using a temperature indicated by a temperature sensor of a control volume for the hydraulic cylinder. 8. The suspension system of claim 1 , wherein the plurality of suspension assemblies consists of a front left suspension assembly having a front left hydraulic cylinder, a front right suspension assembly having a front right hydraulic cylinder, a back left suspension assembly having a back left hydraulic cylinder and a back right suspension assembly having a back right hydraulic cylinder. 9. The agricultural vehicle of claim 8 , wherein the front left hydraulic cylinder is in fluid communication with the back right hydraulic cylinder and the back left hydraulic cylinder is in fluid communication with the front right hydraulic cylinder. 10. The agricultural vehicle of claim 9 , wherein: a first control volume is contained between a first side of the front right hydraulic cylinder, a second side of the back left hydraulic cylinder and a first accumulator; a second control volume is contained between a first side of the back left hydraulic cylinder, a second side of the front right hydraulic cylinder and a second accumulator; a third control volume is contained between a first side of the front left hydraulic cylinder, a second side of the back right hydraulic cylinder and a third accumulator; and a fourth control volume is contained between a first side of the back right hydraulic cylinder, a second side of the front left hydraulic cylinder and a fourth accumulator. 11. The agricultural vehicle of claim 10 , wherein the measured amount of hydraulic fluid in each control volume is determined by adding a first volume comprising a first hydraulic cylinder having a first portion of the control volume, a second volume comprising a second hydraulic cylinder having a second portion of the control volume, and a third volume comprising a hydraulic fluid portion of an accumulator, wherein the volume of the first and second hydraulic cylinders are determined from position indicated by position sensors configured with respect to the first and second hydraulic cylinders, and wherein the volume of the hydraulic fluid portion of the accumulator is determined from the pressure indicated by a pressure sensor. 12. The suspension system of claim 11 , wherein the volume of the hydraulic fluid portion of the accumulator is determined by determining a volume of the gas portion of the accumulator using the ideal gas law and subtracting the volume of the gas portion of the accumulator from a total volume of the accumulator. 13. An agricultural sprayer comprising: a chassis supported by front left, front right, back left and back right suspension assemblies, each suspension assembly comprising a swing frame assembly and a dual action hydraulic cylinder, each hydraulic cylinder comprising a piston rod configured to extend and retract with respect to a base, wherein the swing frame assembly is coupled to the sprayer at a pivot point and is coupled to a wheel at a hub point, and wherein the hydraulic cylinder is operationally coupled to the sprayer at a cylinder point and is also operationally coupled to the swing frame assembly at an actuation point distal from the pivot point such that action of the hydraulic cylinder at the actuation point causes the swing frame assembly to pivot at the pivot point; a plurality of tires, each tire being mounted to a wheel; a sprayer boom extending transversely relative to the chassis; a plurality of position sensors, each position sensor being configured to generate a signal indicating a suspension height; a plurality of electronically controlled valves, each electronically controlled valve being configured to control a flow of hydraulic fluid to and from a control volume for operating a hydraulic cylinder; a plurality of accumulators, each accumulator comprising a hydraulic fluid portion moveable with respect to a gas portion, each accumulator being configured with respect to a hydraulic cylinder, wherein each control volume for operating a hydraulic cylinder includes a hydraulic fluid po