Quantum cascade laser with autonomously aligned external cavity and related methods

That which is claimed is: 1. A quantum cascade laser (QCL) comprising: a QCL crystal having at least one emitting facet, and an active region adjacent said at least one emitting facet, said at least one emitting facet for providing an electromagnetic beam; an optical cavity comprising at least one mirror being external to said QCL crystal, and for redirecting the electromagnetic beam into the active region of said QCL crystal to provide optical feedback; a driver circuit for driving said QCL crystal with a constant current; and a controller coupled to said optical cavity and for dynamically and autonomously aligning said optical cavity based upon at least one error signal from said QCL crystal to maintain stable the optical feedback in said active region of said QCL crystal. 2. The QCL of claim 1 wherein the constant current comprises a plurality of constant current pulses. 3. The QCL of claim 1 wherein the at least one error signal comprises a voltage waveform across said QCL crystal based upon a varying impedance of said QCL crystal. 4. The QCL of claim 3 wherein the voltage waveform includes a plurality of spikes due to mode-hops during application of the constant current to said QCL crystal; and wherein said controller dynamically and autonomously aligns said optical cavity based upon magnitudes of the plurality of spikes. 5. The QCL of claim 3 wherein said controller dynamically and autonomously aligns said optical cavity based upon a minimum value in the voltage waveform during application of the constant current to said QCL crystal. 6. The QCL of claim 1 wherein said QCL crystal comprises a reflecting facet adjacent said active region and opposite said at least one emitting facet; wherein said at least emitting face has an anti-reflection coating thereon; wherein said optical cavity comprises a feedback mirror external to said QCL crystal; and further comprising at least one motor coupled to control said optical cavity to achieve feedback. 7. The QCL of claim 6 wherein said controller is coupled to said at least one motor and aligns said optical cavity by at least repositioning said feedback mirror. 8. The QCL of claim 6 wherein said controller dithers alignment of said feedback mirror during application of the constant current to said QCL crystal. 9. The QCL of claim 1 further comprising at least one motor coupled to control said optical cavity to achieve feedback; wherein said eternal cavity further comprises a collimating optic; and wherein said controller is coupled to said at least one motor and aligns said optical cavity by at least repositioning said collimating optic. 10. The QCL of claim 1 further comprising at least one motor coupled to control said optical cavity to achieve feedback; and wherein said controller is coupled to said at least one motor and aligns said optical cavity by at least repositioning said QCL crystal. 11. The QCL of claim 1 further comprising: an interferometer for receiving the output of said optical cavity; and an optical detector coupled to said interferometer. 12. A spectrometer comprising: a container having at least one vapor sample therein; a quantum cascade laser (QCL) comprising a QCL crystal having at least one emitting facet, and an active region adjacent said at least one emitting facet, said at least one emitting facet for providing an electromagnetic beam, an optical cavity comprising at least one mirror being external to said QCL crystal, and for redirecting the electromagnetic beam into the active region of said QCL crystal to provide optical feedback, said container being positioned to allow the electromagnetic beam within said optical cavity to pass through said container, a portion of the electromagnetic radiation to be extracted from said optical cavity for spectral analysis to determine absorption by the at least one vapor sample in said container, and a driver circuit for driving said QCL crystal with a constant current; and a controller coupled to said optical cavity and for dynamically and autonomously aligning said optical cavity based upon at least one error signal from said QCL crystal to maintain stable the optical feedback in said active region of said QCL crystal. 13. The spectrometer of claim 12 wherein the constant current comprises a plurality of constant current pulses. 14. The spectrometer of claim 12 wherein the at least one error signal comprises a voltage waveform across said QCL crystal based upon a varying impedance of said QCL crystal. 15. The spectrometer of claim 14 wherein the voltage waveform includes a plurality of spikes due to mode-hops during application of the constant current to said QCL crystal; and wherein said controller dynamically and autonomously aligns said optical cavity based upon magnitudes of the plurality of spikes. 16. The spectrometer of claim 14 wherein said controller dynamically and autonomously aligns said optical cavity based upon a minimum value in the voltage waveform during application of the constant current to said QCL crystal. 17. The spectrometer of claim 12 wherein said QCL crystal comprises a reflecting facet adjacent said active region and opposite said at least one emitting facet; wherein said at least emitting face has an anti-reflection coating thereon; wherein said optical cavity comprises a feedback mirror external to said QCL crystal; and further comprising at least one motor coupled to control said optical cavity to achieve feedback. 18. The spectrometer of claim 17 wherein said controller is coupled to said at least one motor and aligns said optical cavity by at least repositioning said feedback mirror. 19. The spectrometer of claim 17 wherein said controller dithers alignment of said feedback mirror during application of the constant current to said QCL crystal. 20. The spectrometer of claim 12 wherein said QCL comprises at least one motor coupled to control said optical cavity to achieve feedback; wherein said eternal cavity further comprises a collimating optic; and wherein said controller is coupled to said at least one motor and aligns said optical cavity by at least repositioning said collimating optic. 21. The spectrometer of claim 12 wherein said QCL comprises at least one motor coupled to control said optical cavity to achieve feedback; and wherein said controller is coupled to said at least one motor and aligns said optical cavity by at least repositioning said QCL crystal. 22. A method of operating a quantum cascade laser (QCL) comprising a QCL crystal having at least one emitting facet, and an active region adjacent the at least one emitting facet, the at least one emitting facet for providing an electromagnetic beam, an optical cavity comprising at least one mirror being external to the QCL crystal, and for redirecting the electromagnetic beam into the active region of said QCL crystal to provide optical feedback, and a driver circuit for driving the QCL crystal with a constant current, the method comprising: dynamically and autonomously aligning the optical cavity based upon at least one error signal from the QCL crystal to maintain stable the optical feedback in the active region of the QCL crystal. 23. The method of claim 22 wherein the constant current comprises a plurality of constant current pulses. 24. The method of claim 22 wherein the at least one error signal comprises a voltage waveform across the QCL crystal based upon a varying impedance of the QCL crysta