Phase modulation device and laser microscope

What is claimed is: 1. A phase modulation device for correcting a wave front aberration generated by an optical system including an objective lens disposed on an optical path of a light flux of light to be emitted from a light source, comprising: a first phase modulation element which includes a plurality of first electrodes disposed to impart to the light flux a first amount of phase modulation to cancel a first phase distribution in accordance with a first ratio of a second aberration component of the wave front aberration to a first aberration component of the wave front aberration, and modulates a phase of the light flux in accordance with a respective first voltage applied to each of the plurality of first electrodes; a second phase modulation element which includes a plurality of second electrodes disposed to impart to the light flux a second amount of phase modulation to cancel a second phase distribution in accordance with a second ratio of the second aberration component of the wave front aberration to the first aberration component of the wave front aberration, the second ratio being smaller than the first ratio, and modulates a phase of the light flux in accordance with a respective second voltage applied to each of the plurality of second electrodes; and a control circuit which controls the first voltages applied to the plurality of first electrodes and the second voltages applied to the plurality of second electrodes in accordance with an optical path length from the objective lens to a light focusing position of the light flux. 2. The phase modulation device according to claim 1 , wherein the first aberration component includes a third-order spherical aberration component of the wave front aberration and the second aberration component includes a fifth-order spherical aberration component of the wave front aberration. 3. The phase modulation device according to claim 1 , wherein the plurality of first electrodes and the plurality of second electrodes are respectively a plurality of concentric annular electrodes about an optical axis of the optical system, and the plurality of first electrodes and the plurality of second electrodes are disposed such that a distance from the optical axis to the electrode which is the nearest to the optical axis among the electrodes which correspond to a local maximum or minimum value of the first amount of phase modulation imparted to the light flux by the first phase modulation element, among the plurality of first electrodes is greater than a distance from the optical axis to the electrode which is the nearest to the optical axis among the electrodes which correspond to a local maximum or minimum value of the second amount of phase modulation imparted to the light flux by the second phase modulation element, among the plurality of second electrodes. 4. A phase modulation device for correcting a wave front aberration generated by an optical system including an objective lens disposed on an optical path of a light flux of light to be emitted from a light source, comprising: a phase modulation element which includes, on one surface of the phase modulation element through which the light flux is transmitted, a plurality of first electrodes disposed to impart to the light flux a first amount of phase modulation to cancel a first phase distribution in accordance with a first ratio of a second aberration component of the wave front aberration to a first aberration component of the wave front aberration; and on the other surface facing the one surface, a plurality of second electrodes disposed to impart to the light flux a second amount of phase modulation to cancel a second phase distribution in accordance with a second ratio smaller than the first ratio of the second aberration component of the wave front aberration to the first aberration component of the wave front aberration; and modulates a phase of the light flux in accordance with a respective first voltage applied to each of the plurality of first electrodes and a respective second voltage applied to each of the plurality of second electrodes; and a control circuit which controls the first voltages applied to the plurality of first electrodes and the second voltages applied to the plurality of second electrodes in accordance with an optical path length from the objective lens to a light focusing position of the light flux. 5. A laser microscope comprising: a coherent light source which irradiates coherent light; a first optical system disposed on an optical path of a light flux of the coherent light which includes an objective lens to focus the light flux on a specimen; a second optical system which transmits a light flux including specimen information derived from the specimen to a detector; and the phase modulation device for correcting a wave front aberration generated by the first optical system; wherein the phase modulation device includes: a first phase modulation element disposed between the coherent light source and the objective lens, the first phase modulation element including a plurality of first electrodes disposed to impart to the light flux a first amount of phase modulation to cancel a first phase distribution in accordance with a first ratio of a second aberration component of the wave front aberration to a first aberration component of the wave front aberration, and modulating a phase of the light flux in accordance with a respective first voltage applied to each of the plurality of first electrodes; a second phase modulation element disposed between the coherent light source and the objective lens, the second phase modulation element including a plurality of second electrodes disposed to impart to the light flux a second amount of phase modulation to cancel a second phase distribution in accordance with a second ratio of the second aberration component of the wave front aberration to the first aberration component of the wave front aberration, the second ratio being smaller than the first ratio, and modulating a phase of the light flux in accordance with a respective second voltage applied to each of the plurality of second electrodes; and a control circuit which controls the first voltages applied to the plurality of first electrodes and the second voltages applied to the plurality of second electrodes in accordance with an optical path length from the objective lens to a light focusing position of the light flux.