Patent Number: 
Section: claims

1. A charged particle beam apparatus comprising:a charged particle source configured to discharge a charged particle beam;charged particle optics that adjusts the charged particle beam on the basis of an input voltage value;scanning means for moving an irradiation point of the charged particle beam with respect to a sample;observing means for obtaining an image of a surface of the sample irradiated with the charged particle beam; anda control unit that sets an adjusted input voltage value to the charged particle optics, the control unit comprising spot pattern forming means for sequentially forming spot patterns at different positions on the sample surface in accordance with different voltage values input to the charged particle optics, and spot pattern analyzing means for analyzing the spot patterns on the image and selecting the adjusted input voltage value corresponding to a spot pattern having the smallest outer diameter and/or the most circular shape of the spot patterns. 2. The charged particle beam apparatus according to claim 1; wherein the spot pattern forming means of the control unit moves the irradiation point of the charged particle beam with respect to the sample by the scanning means by an amount obtained by multiplying the amount of change of the input voltage value by a predetermined coefficient every time when the charged particle beam is irradiated on the sample after setting the input voltage value to the different value. 3. The charged particle beam apparatus according to claim 1; wherein the charged particle optics includes an electrostatic lens configured to focus the charged particle beam to cause the sample to be irradiated therewith by applying a voltage to an electrode of the electrostatic lens, and the control unit causes the spot pattern forming means to form the spot patterns by setting voltage values to be applied to the electrode of the electrostatic lens to different values as the input voltage values and causes the spot pattern analyzing means to select and set the adjusted input voltage value to thereby adjust the focal length of the electrostatic lens. 4. The charged particle beam apparatus according to claim 1; further including a stigmator which includes a multi-pole having a pair of opposed positive poles and a pair of negative poles opposed substantially orthogonally to the direction of arrangement of the positive poles and which corrects the cross-sectional shape of the charged particle beam into a substantially circular shape by applying a voltage between each pair of positive and negative poles of the multi-pole, and wherein the control unit causes the spot pattern forming means to set the voltage value to be applied between the positive poles and the negative poles of the stigmator to different values as input voltage values to form spot patterns, and causes the spot pattern analyzing means to select the spot pattern having the smallest spot characteristic value as the ratio of the short diameter with respect to the long diameter of the outer diameters of the spot pattern in the orthogonal two directions, and set the voltage value to the voltage value corresponding to the spot pattern having the smallest value, so that the beam diameter ratio in the orthogonal two directions of the charged particle beam is adjusted. 5. The charged particle beam apparatus according to claim 4; wherein the spot pattern forming means of the control unit brings the charged particle beam into an over focus state with respect to the sample and forms a first plurality of spot patterns on the surface of the sample with different voltage values, and then brings the charged particle beam into an under focus state with respect to the sample and forms a second plurality of spot patterns on the surface of the sample with the same voltage values as in the case of the over focus state, respectively, and the spot pattern analyzing means of the control unit performs pattern matching between the spot patterns formed in the over focus state and in the under focus state with the same voltage values and selects the set of the spot patterns whose ratio of matching of pattern matching elements is the highest. 6. The charged particle beam apparatus according to claim 5; wherein the spot pattern forming means of the control unit matches the arrangement of the first and second pluralities of spot patterns to the corresponding voltage values between the state of the over focus and in the state of under focus to form the spot patterns. 7. The charged particle beam apparatus according to claim 4; wherein the stigmator includes two of the multi-poles including a first multi-pole and a second multi-pole, the voltage value includes a set of a first voltage value to be applied between the positive pole and the negative pole of the first multi-pole and a second voltage value to be applied between the positive pole and the negative pole of the second multi-pole, and the spot pattern forming means of the control unit combines the first voltage value and the second voltage value in different manners, moves the charged particle beam in a first direction by an amount obtained by multiplying an amount of change of the first voltage value by a predetermined coefficient and in a second direction intersecting the first direction by an amount obtained by multiplying an amount of change of the second voltage value by the coefficient relatively with respect to the sample by the scanning means, and causes the same to be applied a plurality of times. 8. The charged particle beam apparatus according to claim 1; wherein the observing means comprises a scanning electron microscope (SEM) column that scans the sample surface with an electron beam to obtain a SEM image of the sample surface having the spot patterns. 9. The charged particle beam apparatus according to claim 8; further comprising a rare gas ion beam column that irradiates the sample with a rare gas ion beam. 10. A method of adjusting charged particle optics of a charged particle beam apparatus which is configured to irradiate a sample with a charged particle beam and in which the charged particle optics is configured to adjust and set a beam characteristic value of the charged particle beam on the basis of the value of an input voltage applied to the charged particle optics, the method comprising: a spot pattern forming step for forming a plurality of discrete spot patterns at different positions on a surface of a sample by setting the input voltage of the charged particle optics to different value, each corresponding to a different one of the spot patterns, and irradiating the sample with the charged particle beam at different positions, each corresponding to a different one of the set input voltage values; an image forming step for forming an image of the sample surface that has been spot patterned by the charged particle beam; a spot pattern analyzing step for selecting from the image of spot patterns the spot pattern having the smallest value from spot characteristic values which indicate the shapes of the respective spot patterns; and an input voltage value setting step for setting the input voltage value of the charged particle optics to a value equal to the input value corresponding to the charged particle beam irradiated when the spot pattern selected in the spot pattern analyzing step is formed. 11. The method of adjusting charged particle optics according to claim 10; wherein the spot pattern forming step moves an irradiation point of the charged particle beam with respect to the sample by an amount obtained by multiplying an amount of change of the input voltage value by a predetermined coefficient every time when the charged particle beam is irradiated on the sample after setting the input voltage value to the different value. 12. The method of adjusting charged particle optics according to claim 10; wherein the charged particle beam apparatus includes an electrostatic lens configured to focus the charged particle beam to cause the sample to be irradiated therewith by applying a voltage to an electrode of the electrostatic lens, the spot pattern forming step forms the spot patterns by setting voltage values to be applied to the electrode of the electrostatic lens to different values as the input voltage values, and the spot pattern analyzing step selects the spot pattern having the smallest spot characteristic value as the outer diameter of the spot pattern, and sets the input voltage value by the input voltage value setting step, so that the focal length of the electrostatic lens as the beam characteristic value is adjusted. 13. The method of adjusting charged particle optics according to claim 10; wherein the charged particle beam apparatus includes a stigmator which includes a multi-pole having a pair of opposed positive poles and a pair of negative poles opposed substantially orthogonally to the direction of arrangement of the positive poles and which corrects the cross-sectional shape of the charged particle beam into a substantially circular shape by applying a voltage between each pair of positive and negative poles of the multi-pole, the voltage value to be applied between the positive poles and the negative poles of the stigmator is set to different values as input voltage values to form the spot patterns in the spot pattern forming step, the spot pattern having the smallest spot characteristic value is selected as the ratio of the short diameter with respect to the long diameter of the outer diameters of the spot pattern in the orthogonal two directions in the spot pattern analyzing step, and the input voltage value is set in the input voltage value setting step, so that the beam diameter ratio in the orthogonal two directions of the charged particle beam as the beam characteristic value is adjusted. 14. The method of adjusting charged particle optics according to claim 13; wherein the spot pattern forming step includes a first step of bringing the charged particle beam into an over focus state with respect to the sample and forming a first plurality of spot patterns on the surface of the sample with different voltage values, and a second step of bringing the charged particle beam into an under focus state with respect to the sample and forming a second plurality of spot patterns of the surface of the sample with the same voltage values as in the first step, respectively, and the spot pattern analyzing step performs pattern matching between the spot patterns formed in the first step and in the second step with the same voltage values and selects the set of the spot patterns whose ratio of matching of pattern matching elements is the highest. 15. The method of adjusting charged particle optics according to claim 14; wherein the first step and the second step of the spot pattern forming step match the arrangement of the first and second pluralities of spot patterns to the corresponding input voltage values to form the spot patterns. 16. The method of adjusting charged particle optics according to claim 13; wherein the stigmator of the charged particle beam apparatus includes two of the multi-poles including a first multi-pole and a second multi-pole, the voltage value includes a first voltage value to be applied between the positive pole and the negative pole of the first multi-pole and a second voltage value to be applied between the positive pole and the negative pole of the second multi-pole and, in the spot pattern forming step, the first voltage value and the second voltage value are combined in different manners, and the charged particle beam is moved in a first direction by an amount obtained by multiplying an amount of change of the first voltage value by a predetermined coefficient and in a second direction intersecting the first direction by an amount obtained by multiplying an amount of change of the second voltage value by the coefficient relatively with respect to the sample, and applied by a plurality of times. 17. The method of adjusting charged particle optics according to claim 10; wherein the spot pattern analyzing step compares the smallest spot characteristic value and a preset spot reference value and, if the spot characteristic value is larger than the spot reference value, the procedure goes again to the spot pattern forming step, and the spot pattern forming step changes the input voltage value by an amount of change smaller than the amount of change when the input voltage value of the charged particle optics is changed in the previous spot pattern forming step to form the spot pattern. 18. The method of adjusting charged particle optics according to claim 10; wherein in the spot pattern analyzing step, the input voltage value corresponding to the spot pattern having the smallest spot characteristic value is compared with the input voltage values corresponding to the other spot patterns and, if the input voltage value corresponding to the spot pattern having the smallest spot characteristic value is the smallest or the largest, the procedure goes to the spot pattern forming step again, and in the spot pattern forming step, the input voltage value is changed within a range including values smaller than the input voltage value if the input voltage value corresponding to the spot pattern having the smallest spot characteristic value is the smallest, and within a range including values larger than the input voltage value if the input voltage value is the largest to form the spot pattern again. 19. The method of adjusting charged particle optics according to claim 10; wherein the spot pattern analyzing step creates binary data obtained by binarizing the image of the sample on which the spot pattern is formed, and selects the spot pattern having the smallest spot characteristic value from the binary data. 20. The method of adjusting charged particle optics according to claim 10; further comprising an adjustment preparation step for arranging a standard sample and a target sample as the sample, and a processing and observation preparation step for adjusting the position of the target sample with respect to the irradiation point of the charged particle beam, wherein the spot pattern forming step, the spot pattern analyzing step, and the input voltage value setting step for the standard sample are performed after the adjustment preparation step, and the processing and observation preparation step is carried out after the input voltage value setting step. 21. The method of adjusting charged particle optics according to claim 10; wherein the image forming step is performed using a scanning electron microscope (SEM) column to obtain a SEM image of the sample surface that has been spot patterned by the charged particle beam.