Correspondence relation specifying method for adaptive optics system, adaptive optics system, and storage medium storing program for adaptive optics system

1 : A correspondence relation specifying method for an adaptive optics system, which includes a spatial light modulator configured to spatially modulate a phase of an optical image incident on a modulation surface including N (N is a natural number) two-dimensionally arranged regions and a wavefront sensor including a lens array having N two-dimensionally arranged lenses corresponding to the N regions and an optical detection element for detecting a light intensity distribution including M (M is a natural number and M≦N) converging spots formed by the lens array and configured to receive the optical image after the modulation from the spatial light modulator and which compensates for wavefront distortion by controlling a phase pattern displayed in the spatial light modulator based on a wavefront shape of the optical image obtained from the light intensity distribution, wherein a correspondence relation between the region of the spatial light modulator and the converging spot formed in the wavefront sensor is specified while the compensation for the wavefront distortion is executed, the correspondence relation specifying method comprising: a first detecting step of detecting the light intensity distribution through the optical detection element in a state in which a phase pattern for compensating for the wavefront distortion is displayed in a specific target region among the N regions of the spatial light modulator; a second detecting step of detecting the light intensity distribution through the optical detection element in a state in which a spatially non-linear phase pattern is displayed in the specific target region before or after the first detecting step; and a first specifying step of specifying a converging spot corresponding to the specific target region among the M converging spots based on a change in the light intensity distribution between the first detecting step and the second detecting step. 2 : The correspondence relation specifying method for the adaptive optics system according to claim 1 , further comprising: a third detecting step of detecting the light intensity distribution through the optical detection element in a state in which the phase pattern for compensating for the wavefront distortion is displayed in the specific target region and the spatially non-linear phase pattern is displayed in a specific target region separate from the specific target region; and a second specifying step of specifying a converging spot corresponding to the separate specific target region based on a change in the light intensity distribution between the second detecting step and the third detecting step. 3 : The correspondence relation specifying method for the adaptive optics system according to claim 1 , wherein, in the first detecting step, the phase pattern for compensating for the wavefront distortion is displayed in all of the N regions. 4 : The correspondence relation specifying method for the adaptive optics system according to claim 1 , wherein the wavefront distortion is compensated based on the wavefront shape obtained from the light intensity distribution detected in the second detecting step. 5 : The correspondence relation specifying method for the adaptive optics system according to claim 1 , wherein the spatially non-linear phase pattern displayed in the specific target region in the second detecting step includes a random distribution in which a distribution of magnitudes of phases is irregular. 6 : The correspondence relation specifying method for the adaptive optics system according to claim 1 , wherein the spatially non-linear phase pattern displayed in the specific target region in the second detecting step includes a defocus distribution which increases a diameter of the converging spot. 7 : The correspondence relation specifying method for the adaptive optics system according to claim 1 , wherein a plurality of regions which are not adjacent to each other among the N regions of the spatial light modulator are set in the specific target region. 8 : An adaptive optics system comprising: a spatial light modulator configured to spatially modulate a phase of an optical image incident on a modulation surface including N (N is a natural number) two-dimensionally arranged regions; a wavefront sensor including a lens array having N two-dimensionally arranged lenses corresponding to the N regions and an optical detection element for detecting a light intensity distribution including M (M is a natural number and M≦N) converging spots formed by the lens array and configured to receive the optical image after the modulation from the spatial light modulator; and a control unit configured to compensate for the wavefront distortion by controlling a phase pattern displayed in the spatial light modulator based on a wavefront shape of the optical image obtained from the light intensity distribution, wherein the control unit acquires a first light intensity distribution through the light detection element in a state in which a phase pattern for compensating for the wavefront distortion is displayed in a specific target region among the N regions of the spatial light modulator while the compensation for the wavefront distortion is executed, acquires a second light intensity distribution through the optical detection element in a state in which a spatially non-linear phase pattern is displayed in the specific target region, and specifies a converging spot corresponding to the specific target region among the M converging spots based on a change between the first light intensity distribution and the second light intensity distribution. 9 : A storage medium storing a program for an adaptive optics system, which includes a spatial light modulator configured to spatially modulate a phase of an optical image incident on a modulation surface including N (N is a natural number) two-dimensionally arranged regions, a wavefront sensor including a lens array having N two-dimensionally arranged lenses corresponding to the N regions and an optical detection element for detecting a light intensity distribution including M (M is a natural number and M≦N) converging spots formed by the lens array and configured to receive the optical image after the modulation from the spatial light modulator, and a control unit configured to compensate for the wavefront distortion by controlling a phase pattern displayed in the spatial light modulator based on a wavefront shape of the optical image obtained from the light intensity distribution, wherein the program for the adaptive optics system causes the control unit to specify a correspondence relation between the region of the spatial light modulator and the converging spot formed in the wavefront sensor while the compensation for the wavefront distortion is executed, the program for the adaptive optics system causing the control unit to execute: a first detecting step of detecting the light intensity distribution through the optical detection element in a state in which a phase pattern for compensating for the wavefront distortion is displayed in a specific target region among the N regions of the spatial light modulator; a second detecting step of detecting the light intensity distribution through the optical detection element in a state in which a spatially non-linear phase pattern is displayed in the specific target region before or after the first detecting step; and a first specifying step of specifying a converging spot corresponding to the specific target region among the M converging spots based on a change in the light intensity distribution between the first detecting step and the second detecting step.