Method and apparatus for correcting bias error in ring-down spectroscopy

The invention claimed is: 1. An apparatus comprising: a laser source; a ring-down optical resonator that performs cavity ring-down spectroscopy; and a controller that controls activation and deactivation of the laser source, wherein, when the controller activates the laser source, the optical resonator receives coherent optical energy from the laser source, wherein, when the controller deactivates the laser source, optical energy emitted from the laser source into the optical resonator is extinguished at least 100 times faster than a ring-down time of the optical resonator following an instance of deactivation of the laser source with an attenuation of the optical energy from the laser source of at least −50 dB, wherein the laser source includes an optical switch implemented as a double pass device, and wherein the controller includes a processor programmed to operate under control of executable software stored on a non-transitory computer readable medium. 2. The apparatus as in claim 1 wherein the optical switch further comprises an acoustic optical modulator. 3. The apparatus as in claim 1 further comprising a detector that samples an acoustic signal from the ring-down resonator. 4. The apparatus as in claim 3 wherein the laser source further comprises an amplifier driven by the controller. 5. An apparatus comprising: a resonator cavity; a laser coupled to the resonator cavity that excites the resonator cavity with coherent energy from the laser; a controller that sends an instruction that deactivates the laser; a detector that measures an exponential decay of energy within the resonator cavity from an instance of the instruction; and a switch coupled to the controller, wherein the controller controls the laser and the switch to extinguish the coherent energy coupled from the laser to the resonator cavity at least 100 times faster than a ring down time of the resonator cavity after the instance of the instruction with an attenuation of the laser's optical energy of at least −50 dB, wherein the switch is implemented as a double pass device, and wherein the controller includes a processor programmed to operate under control of executable software stored on a non-transitory computer readable medium. 6. The apparatus as in claim 5 wherein the switch further comprises an acoustic optic modulator. 7. The apparatus as in claim 5 wherein the switch further comprises a pair of acoustic optic modulators. 8. An apparatus comprising: a resonator cavity of a cavity ring down spectroscopy detector; a laser coupled to the resonator cavity; a controller that sends first and second instructions to the laser, the laser responding to the first instruction by exciting the resonator cavity of the cavity ring down spectroscopy detector with coherent energy from the laser, and the laser responding to the second instruction by deactivating the laser; a detector that measures an exponential decay of energy within the resonator cavity from an instance of the second instruction; and a switch coupled to the controller, wherein the controller controls the laser and the switch to extinguish the coherent energy coupled from the laser to the resonator cavity at least 100 times faster than a ring down time of the resonator cavity after the instance of the second instruction with an attenuation of the laser's optical energy of at least −50 dB, wherein the switch is implemented as a double pass device, and wherein the controller includes a processor programmed to operate under control of executable software stored on a non-transitory computer readable medium. 9. The apparatus as in claim 8 wherein the switch further comprises an acoustic optic modulator. 10. The apparatus as in claim 8 wherein the switch further comprises a pair of acoustic optic modulators.