Fingerprinting of fluid injection devices

What is claimed is: 1. A method for characterizing a fluid injector, comprising: measuring, by an actuator controller, a plurality of electrical waveforms, each waveform corresponding to power consumption of a selected magnitude of electrical excitation provided to an actuator of a fluid injector; determining, by the actuator controller, a collection of data representative of the plurality of electrical waveforms and based on the measuring of the plurality of electrical waveforms; identifying, by the actuator controller, a pull locus, based on the collection of data; determining, by the actuator controller, a detection threshold level value, based on the collection of data; identifying, by the actuator controller, a first subset of the collection of data representative of a selected first electrical waveform of the plurality of electrical waveforms, based on the detection threshold level value and the collection of data; identifying, by the actuator controller, a representative opening value, based on the collection of data; identifying, by the actuator controller, a representative closing value, based on the representative opening value and the collection of data; identifying, by the actuator controller, an anchor value, based on the collection of data and the first subset; identifying, by the actuator controller, a second subset of the collection of data, representative of a selected second electrical waveform of the plurality of electrical waveforms, based on the collection of data, the pull locus, the first subset, and the representative opening value; identifying, by the actuator controller, a maximum electrical value, based on the second subset; identifying, by the actuator controller, an opening locus based the collection of data, the anchor value, and the maximum electrical value; identifying, by the actuator controller, a hold value based on the collection of data; and providing, by the actuator controller, characteristics associated with the fluid injector comprising the pull locus, the opening locus, the hold value, the anchor value, and the representative closing value. 2. The method of claim 1 , wherein the plurality of electrical waveforms are current waveforms of the fluid injector, the collection of data is a first collection of fluid injector current measurement values representative of the current waveforms, the pull locus is a second collection of fluid injector current measurement values, the representative opening value is a first fluid injector current measurement value, the anchor value is a second fluid injector current measurement value, the maximum electrical value is a third fluid injector current measurement value, and the opening locus is a third collection of fluid injector current measurement values. 3. The method of claim 1 , wherein identifying a pull locus further comprises: selecting one or more third subsets of the collection of data, each of the selected subsets being representative of a successive pair of the plurality of waveforms, each selected pair representing two magnitude-wise successive electrical waveforms; for each of the selected third subsets: determining a differential waveform based on a difference between the pair of waveforms; determining that the differential waveform includes a zero crossing point; and identifying and adding a time wise local maxima of the second waveform of the selected pair to a fourth subset of data; and providing the fourth subset as the pull locus associated with the fluid injector. 4. The method of claim 3 , wherein the time wise first local maxima is the effect of a solenoid armature of the fluid injector starting to move relative to a de-energized state of the fluid injector. 5. The method of claim 3 , wherein identifying a second subset of the collection of data further comprises: identifying the last value of the pull locus; identifying a subset of the collection of data corresponding to the last value; and providing the identified subset as the second subset. 6. The method of claim 1 , wherein identifying the anchor value further comprises: selecting one or more third subsets of the collection of data, each of the selected subsets being representative of a successive pair of the plurality of waveforms, each selected pair representing two magnitude-wise successive electrical waveforms; for each of the selected third subsets: determining a differential waveform based on a difference between the pair of waveforms; determining that the differential waveform is the first differential waveform to include a zero crossing point; and providing the zero crossing point as the anchor value associated with the fluid injector. 7. The method of claim 1 , wherein identifying the opening locus further comprises: selecting one or more third subsets of the collection of data, each of the selected subsets being representative of a successive pair of the plurality of waveforms, each selected pair representing two magnitude-wise successive electrical waveforms of the fluid injector; for each of the selected third subsets: determining a differential waveform based on a difference between the pair of waveforms; adding the determined differential waveform to a collection of differential waveform data; identifying the anchor point within the collection of differential waveform data; identifying the maximum electrical value within the collection of differential waveform data; determining a mathematical representation of a line between the anchor value and the maximum electrical value within the collection of differential waveform data; identifying a collection of values within the collection of differential values that intersect the mathematical representation; and providing the identified collection of values as the opening locus associated with the fluid injector. 8. The method of claim 1 , wherein determining a detection threshold level value further comprises estimating a nominal noise level of one or more of the plurality of electrical waveforms. 9. The method of claim 1 , further comprising actuating a solenoid of the fluid injector with a solenoid actuation waveform based on the representative opening value associated with the fluid injector. 10. The method of claim 1 , wherein identifying the hold value further comprises: identifying a first stable waveform of the fluid injector that includes values described by the pull locus and satisfies one or more stabilization criteria; determining a minimum electrical value based on the first stable waveform; and providing the minimum electrical value as the hold value associated with the fluid injector. 11. The method of claim 1 , further comprising energizing, by the actuator controller, the actuator of the fluid injector with the plurality of electrical excitations. 12. The method of claim 1 , further comprising adjusting, by the actuator controller, the selected magnitude of electrical excitation provided to the actuator of the fluid injector. 13. The method of claim 1 , further comprising providing, by the actuator controller, an output that is indicative of a behavioral change of the fluid injector. 14. A system for characterizing an injector for a fluid injector, comprising: a power controller; a data processing apparatus; and a computer memory storage device storing instructions executable by a computer device and that upon such execution cause the computer device to perform operations comprising: measuring, by the power controller, a plurality of electrical waveforms, each waveform corresponding to power consumption of a selected magnitude of power electrical excit