System and method for calibrating the light output of an optoacoustic probe

What is claimed is: 1. A computer implemented method for calibrating an optoacoustic (OA) probe of an OA imaging system, the method comprising: a. setting a light output control of a first light source of a light subsystem to an initial value; b. pulsing the first light source, thereby delivering light to a OA probe and a volume; c. taking a light measurement from a first sensor of the OA probe, the light delivered along a light path by the light subsystem; d. changing the setting of the light output control of the first light source based upon the light measurement from the first sensor; and e. repeating steps b-d until an operating level is reached; wherein the OA probe includes an optical element comprising an optical window that optically communicates with the light path and the first sensor communicates with the optical window. 2. The computer implemented method of claim 1 , wherein taking a light measurement from the first sensor of the OA probe includes receiving a measured reflection from the optical window, the measured reflection received from the first sensor. 3. The computer implemented method of claim 1 , wherein changing the setting of the light output control is based upon differences between the measurement by the first sensor and a measurement by a second sensor of the OA probe. 4. The computer implemented method of claim 1 , further comprising: f. pulsing a second light source, thereby delivering light to the OA probe and the volume; g. taking a light measurement from a second sensor of the OA probe, the light delivered along the light path by the light subsystem; h. changing the setting of the light output control of the second light source based upon the light measurement from the second sensor; and i. repeating steps f-h until the operating level is reached. 5. The computer implemented method of claim 1 , wherein, OA probe related information is stored in a memory of the computer within the OA probe. 6. The computer implemented method of claim 1 , wherein changing the setting of the light output control of the first light source based upon the light measurement from the first sensor includes predicting the light measurement of the first sensor, and changing the setting of the light output control of the first light source based on a deviation between the predicted light measurement from the first sensor and the light measurement from the first sensor. 7. The computer implemented method of claim 1 , wherein the optical window is spaced from a distal end of a plurality of optical fibers by a gap and the first sensor is located in the gap. 8. An optoacoustic (OA) imaging system, comprising: an OA probe having a distal end configured to contact tissue; an acoustic element and an optical element held in the OA probe at the distal end; a light subsystem having a first light source configured to deliver light along a light path to the OA probe and to a volume; a first sensor within the OA probe configured to measure the light; and a computer configured to execute programming to: a. set a light output control of the first light source to an initial value; b. pulse the first light source, thereby delivering light to the probe and the volume; c. take a measurement from the first sensor; d. change the setting of the light output control of the first light source based upon the measurement from the first sensor; and e. repeat steps b-d until an operating level is reached; wherein the optical element comprises an optical window that optically communicates with the light path and the first sensor communicates with the optical window. 9. The OA imaging system of claim 8 , wherein the first sensor is configured to measure reflection from the optical window. 10. The OA imaging system of claim 8 , wherein the first sensor is positioned to receive light directly from the light path. 11. The OA imaging system of claim 8 , wherein the optical window is spaced from a distal end of a plurality of optical fibers by a gap and the first sensor is located in the gap. 12. The OA imaging system of claim 11 , wherein the light path comprises the plurality of optical fibers, and wherein the first sensor is configured to receive light from a distal end of the plurality optical fibers. 13. The OA imaging system of claim 8 , wherein the first sensor is coupled to the optical window. 14. The OA imaging system of claim 8 , wherein the first sensor is arranged to detect the light after the light is reflected from a surface of the volume. 15. The OA imaging system of claim 8 , further comprising a second sensor within the OA probe, the computer configured to execute a programming to control a variation of the light output of the probe based on a difference between the measurement of the first sensor and a measurement by the second sensor. 16. The OA imaging system of claim 8 , wherein the light subsystem includes a second light source configured to deliver light along the light path to the OA probe and to the volume; and wherein the computer is further configured to execute programming to pulse the second light source, thereby delivering light to the probe and the volume. 17. The OA imaging system of claim 8 , wherein the computer includes a memory to store OA probe related information. 18. The OA imaging system of claim 8 , wherein the optical window includes a coating to reduce energy absorbed by the optical window. 19. The OA imaging system of claim 8 , wherein the computer is further configured to execute programming to predict the measurement at the first sensor; and change the setting of the light output control of the first light source based on a deviation between the predicted measurement from the first sensor and the measurement from the first sensor. 20. The OA imaging system of claim 8 , wherein the light path includes the optical window.