Optical-fiber-compatible sensor

What is claimed is: 1. An acoustic sensor system comprising: a first acoustic sensor comprising: a first reflective element; and a first optical fiber positioned relative to the first reflective element such that light emitted from the first optical fiber is reflected by the first reflective element, wherein an end of the first optical fiber and the first reflective element form a first optical cavity therebetween, the first optical cavity comprising a liquid medium; a second acoustic sensor comprising: a second reflective element; and a second optical fiber positioned relative to the second reflective element such that light emitted from the second optical fiber is reflected by the second reflective element, wherein an end of the second optical fiber and the second reflective element form a second optical cavity therebetween, the second optical cavity comprising the liquid medium; a reservoir comprising the liquid medium; and plurality of channels along which the liquid medium can move between the first optical cavity, the second optical cavity, and the reservoir. 2. The acoustic sensor of claim 1 , wherein the liquid medium comprises water. 3. The acoustic sensor of claim 1 , wherein the first reflective element comprises a first diaphragm configured to move in response to changes of pressure applied to the acoustic sensor and the second reflective element comprises a second diaphragm configured to move in response to the changes of pressure applied to the acoustic sensor. 4. The acoustic sensor of claim 1 , wherein the first acoustic sensor is responsive to acoustic signals having at least a first signal level and the second acoustic sensor is responsive to acoustic signals having at least a second signal level higher than the first signal level. 5. The acoustic sensor of claim 1 , wherein the first acoustic sensor has a first resonance frequency, the second acoustic sensor has a second resonance frequency, and the reservoir has a Hemholtz resonance frequency, wherein the first resonance frequency, the second resonance frequency, and the Hemholtz resonance frequency are substantially equal to one another. 6. The acoustic sensor of claim 1 , wherein the first acoustic sensor has a first resonance frequency, the second acoustic sensor has a second resonance frequency, and the reservoir has a Hemholtz resonance frequency, wherein the Helmholtz resonance frequency and the first resonance frequency differ from one another by less than 10% of either the Helmholtz resonance frequency and the first resonance frequency, and the Helmholtz resonance frequency and the second resonance frequency differ from one another by less than 10% of either the Helmholtz resonance frequency and the second resonance frequency. 7. The acoustic sensor of claim 1 , wherein the reservoir comprises a gas bubble within the liquid material. 8. The acoustic sensor of claim 1 , further comprising a focusing element within an optical path of the light emitted from the first optical fiber and reflected by the first reflective element, wherein a mode-field diameter of the light reflected by the first reflective element to the end of the first optical fiber is matched to a mode-field diameter of the first optical fiber. 9. The acoustic sensor of claim 7 , wherein the gas bubble has a width larger than 100 microns. 10. The acoustic sensor of claim 7 , wherein the liquid material comprises water. 11. An acoustic sensor comprising: a reflective element configured to move in response to changes of pressure applied to the acoustic sensor; an optical fiber positioned relative to the reflective element such that light emitted from the optical fiber is reflected by the reflective element, wherein an end of the optical fiber and the reflective element form an optical cavity therebetween; and a focusing element within an optical path of the light emitted from the optical fiber and reflected by the reflective element, the focusing element comprising a curved portion of the reflective element. 12. The acoustic sensor of claim 11 , wherein the focusing element comprises a lens. 13. The acoustic sensor of claim 11 , wherein the reflective element comprises a diaphragm and the diaphragm comprises the focusing element. 14. The acoustic sensor of claim 11 , further comprising: a backchamber comprising a liquid material in fluidic communication with the optical cavity; and a gas volume within the liquid material of the backchamber, the gas volume providing a compressibility in the backchamber such that the acoustic sensor has a minimum detectable pressure less than 10μPa/Hz 1/2 in a frequency range of 100Hz to 10kHz. 15. The acoustic sensor of claim 14 , wherein the gas volume comprises a gas bubble within the liquid material. 16. The acoustic sensor of claim 15 , wherein the gas bubble has a width larger than 100 microns. 17. The acoustic sensor of claim 14 , wherein the liquid material comprises water. 18. The acoustic sensor of claim 14 , further comprising one or more fluid conduits configured to allow the liquid material to flow between the optical cavity and the backchamber.