Calibration process for femtosecond laser intraocular lens modification system using video and oct targeting

What is claimed is: 1 . A method for calibrating and operating an ophthalmic laser system, comprising: generating a pulsed laser beam; controlling a position of an XY scanner of the ophthalmic laser system to scan the laser beam in XY directions in a glass coverslip placed in front of laser delivery optics of the ophthalmic laser system to generate fluorescence signals in the coverslip via multiphoton absorption; controlling an imaging subsystem of the ophthalmic laser system to measure XY positions of the fluorescence signals; and calibrating the XY scanner by correlating the XY positions of the fluorescence signals measured by the imaging subsystem to the position of the XY scanner. 2 . The method of claim 1 , further comprising: controlling a position of a Z scanner of the ophthalmic laser system to scan the laser beam in a Z direction through the coverslip; controlling the imaging subsystem to measure a fluorescence signal intensity as a function of a Z scanner position; finding a Z scanner position that corresponds to a peak of the measured fluorescence signal intensity; controlling the imaging subsystem to measure a real space Z position of the coverslip; and calibrating the Z scanner by correlating the measured real space Z position and the Z scanner position that corresponds to the peak of the measured fluorescence signal intensity. 3 . The method of claim 2 , further comprising, after calibrating the XY scanner and calibrating the Z scanner, operating the ophthalmic laser system to treat a patient's eye, including generating a treatment laser beam and scanning the treatment laser beam in the patient's eye using the calibrated XY scanner and Z scanner. 4 . The method of claim 2 , wherein the step of controlling the imaging subsystem of the ophthalmic laser system to measure the XY positions of the fluorescence signals includes controlling a video camera of the imaging subsystem to measure the XY positions of the fluorescence signals, wherein the step of controlling the imaging subsystem to measure the fluorescence signal intensity includes controlling the video camera to measure the fluorescence signal intensity, and wherein the step of controlling the imaging subsystem to measure the real space Z position of the coverslip includes controlling an OCT (optical coherence tomography) device of the imaging subsystem to measure the real space Z position of the coverslip. 5 . A method for calibrating and operating an ophthalmic laser system, comprising: generating a low energy pulsed laser beam, the low energy laser beam having a pulse energy configured to cause formation of damages in an IOL (intraocular lens) material only after multiple irradiations; controlling a laser delivery optical subsystem of the ophthalmic laser system to repeatedly scan the low energy laser beam in a piece of the IOL material; controlling an imaging subsystem of the ophthalmic laser system to measure formation of damages in the piece of IOL material after repeats of laser scans, and to determine a rate of damage formation; and determining an effective laser intensity of the laser beam based on the rate of damage formation. 6 . The method of claim 5 , further comprising: determining a laser treatment plan based on the effective laser intensity; and operating the ophthalmic laser system according to the laser treatment plan to treat a patient's eye, including generating a treatment laser beam and scanning the treatment laser beam in the patient's eye. 7 . The method of claim 5 , wherein the step of controlling the imaging subsystem of the ophthalmic laser system to measure the formation of damages in the piece of IOL material includes controlling a video camera or an OCT (optical coherence tomography) device of the ophthalmic laser system to measure the formation of damages in the piece of IOL material.