Onboard diagnosis and compensation for tip wear in fuel injector

What is claimed is: 1. A method of operating a fuel system for an internal combustion engine comprising: energizing an electrical actuator in a fuel injector fluidly connected to a pressurized fuel reservoir in a fuel system; opening an outlet check in the fuel injector based on the energizing an electrical actuator to inject a fuel from the fuel injector into a cylinder in an engine at a test point on a tip wear-sensitive region of a fuel injector delivery curve adjacent to a tip wear-insensitive region of the fuel delivery curve; measuring a pressure drop in the pressurized fuel reservoir caused by the injection of the fuel; calculating a pressure drop error based on a difference between the measured pressure drop and a target pressure drop; and producing an injector health signal based on the calculated pressure drop error; wherein the test point is between a lower reference point, and a higher, scaling reference point on the tip wear-insensitive region of the fuel injector delivery curve. 2. The method of claim 1 further comprising turning off each of a plurality of other fuel injectors and a high-pressure fuel pump supplying the pressurized fuel reservoir, prior to the energizing an electrical actuator, the plurality of other fuel injectors being fluidly connected to the pressurized fuel reservoir. 3. The method of claim 2 wherein: the injecting a fuel is one of a plurality of injections of fuel at the test point performed sequentially in a plurality of cam cycles; and the measuring a pressure drop is one of a plurality of measurements of pressure drop stepped down sequentially and each caused by one of the plurality of injections of fuel at the test point. 4. The method of claim 3 wherein the calculating a pressure drop error includes calculating the pressure drop error based on the plurality of measurements of pressure drop, and further comprising calculating a numerical wear factor for the fuel injector based on the pressure drop error. 5. The method of claim 4 further comprising calculating a prognostic service life term for the fuel injector based on the numerical wear factor and a stored wear factor history. 6. The method of claim 1 wherein the lower reference point includes a zeroing reference point. 7. The method of claim 6 wherein the tip wear-sensitive region of the fuel injector delivery curve includes a ballistic region of the fuel injector delivery curve. 8. The method of claim 7 further comprising operating the fuel system to preestablish the zeroing reference point and the higher, scaling reference point. 9. The method of claim 1 wherein the measured pressure drop is less than the target pressure drop, and the injector health signal includes a pass/fail signal based on a magnitude of the pressure drop error. 10. A fuel control system comprising: a fueling control unit structured to: determine a test point on a tip wear-sensitive region of a fuel injector delivery curve of a fuel injector, the tip wear-sensitive region including a ballistic region of the fuel injector delivery curve; determine a reference point on a tip wear-insensitive region of the fuel injector delivery curve; energize an electrical actuator in the fuel injector to inject a fuel, via opening an outlet check of the fuel injector, at the test point on the tip wear-sensitive region of the fuel injector delivery curve; store a measurement of a pressure drop in a pressurized fuel reservoir caused by the injection of fuel; and produce an injector health signal based on the stored measurement of a pressure drop. 11. The fuel control system of claim 10 wherein the fueling control unit is further structured via operating the fuel injector to determine the test point between a zeroing point and the reference point, and the reference point including a higher, scaling point on the tip wear-insensitive region of the fuel injector delivery curve. 12. The fuel control system of claim 10 wherein the fueling control unit is further structured to compare the stored measurement of a pressure drop to a target pressure drop, and wherein the stored measurement of a pressure drop is less than the target pressure drop. 13. The fuel control system of claim 10 wherein the fueling control unit is further structured to: energize the electrical actuator a plurality of times to perform a plurality of injections of fuel from the fuel injector at the test point sequentially; store a plurality of pressure drop measurements stepped down sequentially and each caused by one of the plurality of injections of fuel; and calculate a pressure drop error based on the stored plurality of pressure drop measurements. 14. The fuel control system of claim 13 wherein the fueling control unit is further structured to determine a numerical wear factor for the fuel injector based on the pressure drop error. 15. The fuel control system of claim 13 wherein the fueling control unit is further structured to determine the pressure drop error based on a measured plurality of pressure drops caused by a plurality of fuel injections at a second test point on the ballistic region of the fuel injector delivery curve. 16. A fuel control system comprising: a fueling control unit structured to: determine a test point on a tip wear-sensitive region of a fuel injector delivery curve of a fuel injector; energize an electrical actuator in the fuel injector to inject a fuel, via opening an outlet check of the fuel injector, at the test point on the tip wear-sensitive region of the fuel injector delivery curve; store a measurement of a pressure drop in a pressurized fuel reservoir caused by the injection of fuel; produce an injector health signal based on the stored measurement of a pressure drop; energize the electrical actuator a plurality of times to perform a plurality of injections of fuel from the fuel injector at the test point sequentially; store a plurality of pressure drop measurements stepped down sequentially and each caused by one of the plurality of injections of fuel; calculate a pressure drop error based on the stored plurality of pressure drop measurements; determine a numerical wear factor for the fuel injector based on the pressure drop error; and calculate a prognostic injector service life term based on the numerical wear factor. 17. A fuel system for an internal combustion engine comprising: a pressurized fuel reservoir; a pressure sensor coupled to the pressurized fuel reservoir; a plurality of fuel injectors fluidly connected to the pressurized fuel reservoir and each including a control valve electrical actuator, and an outlet check coupled to the control valve electrical actuator; and a fueling control unit coupled to the pressure sensor, and in control communication with each control valve electrical actuator, and including an injector wear compensation controller; the injector wear compensation controller being structured to: energize each control valve electrical actuator to inject a fuel from the respective fuel injector; receive pressure measurements from the pressure sensor indicative of a pressure drop in the pressurized fuel reservoir caused by each respective injection of fuel; calculate a pressure drop error for each respective fuel injector based on the corresponding pressure measurements; electronically trim each respective fuel injector based on the corresponding pressure drop error; calculate a numerical wear factor for each fuel injector based on the respective pressure drop error; and calculate a prognostic injector service life term for each fuel injector