Variable geometry turbocharger prognostics

What is claimed is: 1. A diagnostic system for a machine with a combustion engine and a variable geometry turbocharger, the variable geometry turbocharger including a vane position sensor, the diagnostic system comprising: a controller configured to monitor an output from the vane position sensor indicative of a position of the vane of the turbocharger during a diagnostic procedure, calculate a learned span value of the turbocharger based on the output of the vane position sensor during the diagnostic procedure and a reference vane position sensor value, access a plurality of stored learned span values, each calculated during a different one of a plurality of diagnostic procedures performed over a period of time, perform a first regression analysis to predict an expected learned span value at a defined future time using the calculated learned span value and the plurality of stored learned span values, and generate an alert message when the expected learned span value is indicative of a potential future fault of the turbocharger. 2. The diagnostic system of claim 1 , wherein the defined future time of the expected learned span value is approximately 50 hours after a most recent diagnostic procedure. 3. The diagnostic system of claim 1 , wherein the reference vane position sensor value corresponds to a sensor value from a calibration, and wherein the learned span value corresponds to a ratio of the output of the vane position sensor during the diagnostic procedure to the reference van position sensor value. 4. The diagnostic system of claim 1 , wherein the controller is configured to determine the expected learned span value is indicative of a potential future fault of the turbocharger when the expected learned span value is outside of an operating learned span range. 5. The diagnostic system of claim 1 , wherein the controller is configured to access a second plurality of stored learned span values, the second plurality of stored learned span values being a sub-set of the first plurality of stored learned span values, and perform a second regression analysis to predict a second expected learned span value at the defined future time using the calculated learned span value and the sub-set of the plurality of stored learned span values. 6. The diagnostic system of claim 5 , wherein the controller is configured to identify a condition of the machine based on a comparison of the first expected learned span value and the second expected learned span value, a comparison of the first regression analysis and the second regression analysis, or both. 7. The diagnostic system of claim 6 , wherein the controller is configured to identify a change of operating condition of the machine when a difference between a first rate of change associated with the first regression analysis and a second rate of change associated with the second regression analysis exceeds a predetermined threshold. 8. The diagnostic system of claim 6 , wherein the controller is configured to identify a turbocharger maintenance condition when the comparison of the first regression analysis and the second regression analysis indicates a discontinuity in the plurality of stored learned span values. 9. The diagnostic system of claim 6 , wherein the controller is configured to identify a turbocharger maintenance condition when a first slope associated with the first regression analysis has a different sign than a second slope associated with the second regression analysis. 10. The diagnostic system of claim 6 , wherein the controller is configured to identify a damaged part condition when a comparison between a first slope associated with the first regression analysis and a second slope associated with the second regression analysis exceeds a predetermined threshold, and wherein the second slope is greater than the first slope. 11. The diagnostic system of claim 6 , wherein the second plurality of learned span values includes more recent learned span values than the first plurality of learned span values. 12. The diagnostic system of claim 1 , wherein the controller is positioned within the machine, and wherein the controller is configured to access the plurality of stored learned span values by accessing a non-transitory computer-readable memory positioned within the machine. 13. The diagnostic system of claim 1 , wherein the controller is at a location that is remote from a location of the machine, and wherein the machine includes a communication transceiver configured to transmit the output from the vane position sensor indicative of a position of the vane of the turbocharger at the time of the diagnostic procedure, and the plurality of stored learned span values to the controller. 14. The diagnostic system of claim 1 , wherein the alert message includes instructing a technician to schedule a service call for the machine. 15. The diagnostic system of claim 1 , wherein the machine also includes an electronic control module, and the diagnostic system further comprising a connector configured to connect the diagnostic system to the electronic control module of the machine. 16. A method of diagnosing a machine with a combustion engine, and a variable geometry turbocharger, the variable geometry turbocharger including a vane position sensor, the method comprising: monitoring an output from the vane position sensor indicative of a position of a vane of the turbocharger during a diagnostic procedure; calculating a learned span value of the turbocharger based on the output of the vane position sensor during the diagnostic procedure and a reference vane position sensor value; accessing a plurality of stored learned span values, each calculated during a different one of a plurality of diagnostic procedures performed over a period of time; performing a first regression analysis to predict an expected learned span value at a defined future time using the calculated learned span value and the plurality of stored learned span values; generating an alert message when the expected learned span value is indicative of a potential future fault of the turbocharger. 17. The method of claim 16 , further comprising accessing a second plurality of stored learned span values, the second plurality of stored learned span values being a sub-set of the first plurality of learned span values; performing a second regression analysis to predict a second expected learned span value at the defined future time using the calculated learned span value and the second plurality of stored learned span values; identifying a condition of the machine based on a comparison of the first expected learned span value and the second expected learned span value, a comparison of the first regression analysis and the second regression analysis, or both. 18. The method of claim 16 , further comprising determining that an expected learned span value is indicative of a potential future fault of the turbocharger when the expected learned span value operates outside an operating learned span range. 19. The method of claim 17 , wherein identifying the condition includes identifying a change of operating condition of the machine when a difference between a first slope associated with the first regression analysis and a second slope associated with the second regression analysis exceeds a predetermined threshold. 20. The method of claim 17 , wherein identifying the condition includes identifying a turbocharger maintenance condition when the comparison between a first slope associated with the first regression analysis