Modal corrector mirror with compliant actuation for optical aberrations

What is claimed is: 1. A laser resonator comprising: a cavity bounded by an end mirror and output coupler; one or more gain media between the end mirror and output coupler; one or more fold mirrors between the end mirror and output coupler, each of the one or more fold mirrors being rotatable around its principal axis to correct lower spatial frequency error within the cavity; and a modal corrector mirror between the end mirror and output coupler, and separate from the one or more fold mirrors, the modal corrector mirror comprising: a controllable-profile faceplate including an optically-treated front surface; and an array of static actuators comprising a plurality of adjustable elements with a respective plurality of compliant mechanisms located between the plurality of adjustable elements and faceplate, each static actuator of the array of static actuators comprising: an adjustable element of the plurality of adjustable elements; and a compliant mechanism of the respective plurality of compliant mechanisms, the compliant mechanism being located between the adjustable element and faceplate, the adjustable element being configured to exert a selectable, localized push-pull force on the faceplate via the compliant mechanism, and the compliant mechanism being configured to scale the respective force, to correct residual higher spatial frequency error within the cavity, and the modal corrector mirror including only the plurality of adjustable elements with the respective plurality of complaint mechanisms located between the plurality of adjustable elements and faceplate. 2. The laser resonator of claim 1 further comprising: one or more statically-actuated mirrors between the end mirror and output coupler, the one or more statically-actuated mirrors being separate from the modal corrector mirror and configured to correct lower frequency error within the cavity, the modal corrector mirror being configured to correct residual higher spatial frequency error within the cavity. 3. The laser resonator of claim 1 , wherein the adjustable element comprises an actuating screw. 4. The laser resonator of claim 1 , wherein the compliant mechanism has a stiffness less than that of the faceplate. 5. The laser resonator of claim 1 , wherein the compliant mechanism has a stiffness selected based on a stiffness of the faceplate. 6. A method comprising: measuring aberrations of an optical wavefront propagating in a laser resonator including a cavity and one or more fold mirrors within the cavity; rotating each of the one or more fold mirrors around its principal axis to correct lower spatial frequency error within the cavity; calculating a conjugate correction figure from the measured aberrations; and applying the conjugate correction figure to a modal corrector mirror within the cavity of the laser resonator to correct residual higher spatial frequency error within the cavity, the modal corrector mirror being separate from the one or more fold mirrors and comprising: a controllable-profile faceplate including an optically-treated front surface; and an array of static actuators comprising a plurality of adjustable elements with a respective plurality of compliant mechanisms located between the plurality of adjustable elements and faceplate, each static actuator of the array of static actuators comprising: an adjustable element of the plurality of adjustable elements; and a compliant mechanism of the respective plurality of compliant mechanisms, the compliant mechanism being located between the adjustable element and faceplate, the adjustable element being configured to exert a selectable, localized push-pull force on the faceplate via the compliant mechanism, and the compliant mechanism being configured to scale the respective force, and the modal corrector mirror including only the plurality of adjustable elements with the respective plurality of compliant mechanisms located between the plurality of adjustable elements and faceplate, wherein applying the conjugate correction figure comprises: actuating one or more adjustable elements of the array of static actuators; exerting push-pull forces on the faceplate by the adjustable elements via respective compliant mechanisms between the adjustable elements and faceplate; and controlling the profile of the front surface of the faceplate in accordance with the push-pull forces. 7. The method of claim 6 , wherein the actuating one or more adjustable elements, exerting push-pull forces and controlling the profile of the front surface occur until a figure of the front surface matches or nearly matches the conjugate correction figure. 8. The method of claim 6 , wherein the laser resonator further includes one or more statically-actuated mirrors within the cavity, the one or more statically-actuated mirrors being separate from the modal corrector mirror, and wherein the method further comprises: applying a second conjugate correction factor to the one or more statically-actuated mirrors to correct residual lower frequency error within the cavity, the conjugate correction figure being applied to the modal corrector mirror to correct residual higher spatial frequency error within the cavity.