System and method for analyzing fuel for fleet calibration

The invention claimed is: 1. A control system for a multiple fuel internal combustion engine on a machine in a fleet of machines, the control system comprising: a gas analyzer configured to monitor in real-time one or more characteristics of a gaseous fuel being supplied to the engine; a fleet management data monitoring module; a cylinder pressure sensor associated with one or more cylinders of the engine; a data collection module configured to receive: real-time fuel characteristics measurements from the gas analyzer; fleet management data characteristic of one or more operational parameters, fuel usage, and performance results for machines in the fleet; and real-time cylinder pressure measurements from the cylinder pressure sensors; and an engine electronic control module configured to: calculate one or more actual combustion parameter values from the real-time cylinder pressure measurements; compare the calculated one or more actual combustion parameter values for each cylinder to predetermined combustion parameter values to determine any difference therebetween, wherein the predetermined combustion parameter values are derived independently from any actual combustion parameter values based on real-time sensor measurements; assign weights to fuel characteristics data, cylinder pressure data, and fleet management data; and control at least one of fuel injection of the gaseous fuel and ignition timing based on the weighted data and any difference between the calculated actual combustion parameter values for each cylinder and the predetermined combustion parameter values. 2. The control system of claim 1 , wherein the engine electronic control module is further configured to receive the predetermined combustion parameter values from a memory storage. 3. The control system of claim 2 , wherein the predetermined combustion parameter values from the memory storage are combustion parameter values based on a theoretical power output that the multiple fuel internal combustion engine can produce with the same types and quantities of fuel as are currently being combusted by the engine while staying within allowable stress limits for the engine. 4. The control system of claim 2 , wherein the predetermined combustion parameter values from the memory storage are combustion parameter values based on a theoretical amount of emissions that the multiple fuel internal combustion engine will produce with the same types and quantities of fuel as are currently being combusted by the engine. 5. The control system of claim 1 , wherein the calculated one or more actual combustion parameter values and the predetermined combustion parameter values include one or more of peak cylinder pressure, indicated mean effective pressure (IMEP), maximum heat released, crank angle of start of combustion, crank angle of center of combustion, and crank angle of opening or closing of an inlet or outlet valve for each of the cylinders of the multiple fuel internal combustion engine. 6. The control system of claim 5 , wherein the predetermined combustion parameter values are combustion parameter values based on a theoretical power output that the multiple fuel internal combustion engine can produce with the same types and quantities of fuel as are currently being combusted by the engine. 7. The control system of claim 1 , wherein the engine electronic control module is further configured to control the timing of one or more of fuel injection of at least two different types of fuel and ignition of the at least two different types of fuel. 8. The control system of claim 1 , further including the engine electronic control module being configured to recalculate one or more actual combustion parameter values from new real-time cylinder pressure measurements taken after the engine electronic control module controls fuel injection of at least two different types of fuel in order to reduce any difference between the calculated actual combustion parameter values for each cylinder and the predetermined combustion parameter values, the recalculation by the engine electronic control module continuing in a closed loop process until the difference between the calculated actual combustion parameter values and the predetermined combustion parameter values is less than a predetermined threshold. 9. The control system of claim 1 , wherein the engine electronic control module is further configured to receive the predetermined combustion parameter values from a calculation module configured to calculate the predetermined combustion parameter values using known, physics-based calculations based on the physical parameters of the engine, real-time characteristics of the fuel, and known thermodynamics of the combustion process for each type of fuel being used by the multiple fuel internal combustion engine. 10. A multiple fuel internal combustion engine in a machine of a fleet of machines, the engine operable in a combined liquid and gaseous fuel mode, comprising: a plurality of cylinders; a real-time cylinder pressure sensor associated with each of the plurality of cylinders; a gas composition and quality sensor associated with a supply of the gaseous fuel; a fleet management data collection module; a cylinder liner temperature sensor associated with each of the plurality of cylinders; a liquid fuel injection system; a gaseous fuel injection system; and a control system, the control system comprising: a data collection module configured to receive real-time cylinder pressure measurements from each of the cylinder pressure sensors, calculate one or more actual combustion parameter values from the real-time cylinder pressure measurements, receive fleet management data, and assign weights to fuel composition and quality data, cylinder pressure data, cylinder liner temperature data, and fleet management data; an engine electronic control module configured to receive the calculated one or more actual combustion parameter values from the data collection module and compare the calculated one or more actual combustion parameter values for each cylinder to predetermined combustion parameter values to determine any difference therebetween, wherein the predetermined combustion parameter values are derived independently from any actual combustion parameter values based on real-time sensor measurements; and a process control module configured to control fuel injection of the fuel supplied to each cylinder based on the weighted data and any difference between the calculated actual combustion parameter values for each cylinder and the predetermined combustion parameter values. 11. The multiple fuel internal combustion engine of claim 10 , wherein the engine electronic control module is further configured to receive the predetermined combustion parameter values from a memory storage. 12. The multiple fuel internal combustion engine of claim 11 , wherein the predetermined combustion parameter values from the memory storage are combustion parameter values based on a theoretical power output that the multiple fuel internal combustion engine can produce with the same types and quantities of fuel as are currently being combusted by the engine while staying within allowable stress limits for the engine. 13. The multiple fuel internal combustion engine of claim 11 , wherein the predetermined combustion parameter values from the memory storage are combustion parameter values based on a theoretical amount of emissions that the multiple fuel internal combustion engine will produce with the same types and quantities of fuel as are currently being combusted by the engine. 14. The multiple fuel internal combus