Data correction method in fine particle measuring device and fine particle measuring device

The invention claimed is: 1. A data correction method for a fine particle measurement device, comprising: an intensity detection procedure capable of detecting light generated from a fine particle by emitting light onto the fine particle flowing through a channel, and obtaining intensity information about the light; a position detection procedure capable of obtaining position information about the fine particle relative to a central position within the channel at a point when the fine particle passes through the emitted light by forming an image pattern divided into a plurality of light reception areas such that the image pattern changes according to a flow position of the fine particle within the channel at the point when the fine particle passes through the emitted light wherein the position information about the fine particle is obtained in a Z axis direction as the position information, and the Z axis direction is perpendicular to an X axis direction which is an emission direction of light onto the fine particle and a Y axis direction which is a flow direction of the fine particle; and a correction procedure for correcting the intensity information on the basis of the position information. 2. The data correction method according to claim 1 , wherein in the position detection procedure, the position information about the fine particle is obtained in the X axis direction. 3. The data correction method according to claim 2 , wherein in the position detection procedure, a detection device receives light of an S polarization component which is separated from scattered light generated from the fine particle and given astigmatism, and a light reception position of the S polarization component on the detection device is obtained as the position information. 4. The data correction method according to claim 3 , wherein in the position detection procedure, a detection device of which light reception surface is divided into multiple areas is used as the detection device. 5. The data correction method according to claim 4 , wherein a detection device of which light reception surface is divided into four areas, which are an area A, an area B, an area C, and an area D, in a lattice manner is used as the detection device, and the position information about the fine particle in the Z axis direction is obtained from a difference Δ1 (A−C) of detection values in the area A and the area C which is not adjacent to the area A. 6. The data correction method according to claim 5 , wherein in the position detection procedure, the position information about the fine particle in the X axis direction is obtained from a difference Δ2 ((A+C)−(B+D)) between a summation (A+C) of detection values in the area A and the area C and a summation (B+D) of detection values in the area B and the area D. 7. The data correction method according to claim 6 , wherein in the correction procedure, the intensity information is corrected on the basis of at least one of the difference Δ1 or the difference Δ2. 8. The data correction method according to claim 7 , wherein a quadrant photodiode is used as the detection device. 9. The data correction method according to claim 6 , wherein in the correction procedure, only the intensity information about the fine particle where at least one of the difference Δ1 or the difference Δ2 is within a predetermined range is extracted. 10. A fine particle measurement device comprising: a light illumination unit configured to emit light onto a fine particle flowing through a channel; a light detection unit configured to detect light generated from the fine particle; a position detection unit configured to obtain position information about the fine particle relative to a central position within the channel at a point when the fine particle passes through the emitted light, by forming an image pattern divided into a plurality of light reception areas such that the image pattern changes according to a flow position of the fine particle within the channel at the point when the fine particle passes through the emitted light, wherein the position information about the fine particle is obtained in a Z axis direction as the position information, and the Z axis direction is perpendicular to an X axis direction which is an emission direction of light onto the fine particle and a Y axis direction which is a flow direction of the fine particle; and an arithmetic computation unit configured to correct, on the basis of the position information, intensity information about light generated from the fine particle obtained by the light detection unit. 11. The fine particle measurement device according to claim 10 , wherein the position detection unit includes: a first spectral device configured to separate scattered light generated from the fine particle into an S polarization component and a P polarization component; an S polarization detection device configured to receive light of the S polarization component; and an astigmatism device provided between the first spectral device and the S polarization detection device to give astigmatism to the S polarization component, and a light reception position of the S polarization component on the S polarization detection device is obtained as the position information. 12. The fine particle measurement device according to claim 11 , wherein a light reception surface of the S polarization detection device is divided into a plurality of areas. 13. The fine particle measurement device according to claim 12 , wherein the light reception surface of the S polarization detection device is divided into four areas, which are an area A, an area B, an area C, and an area D, in a lattice manner. 14. The fine particle measurement device according to claim 13 , wherein the arithmetic computation unit corrects the intensity information on the basis of at least one of: a difference Δ1 (A−C) of detection values in the area A and the area C which is not adjacent to the area A, or a difference Δ2 ((A+C)−(B+D)) between a summation (A+C) of detection values in the area A and the area C and a summation (B+D) of detection values in the area B and the area D. 15. The fine particle measurement device according to claim 14 , wherein the S polarization detection device is a quadrant photodiode. 16. The fine particle measurement device according to claim 15 , wherein the astigmatism device is a cylindrical lens. 17. The fine particle measurement device according to claim 16 further comprising a second spectral device configured to separate the light generated from the fine particle into the scattered light and fluorescence, and wherein the light detection unit includes a P polarization detection device configured to detect the P polarization component and a fluorescence detection device configured to detect the fluorescence. 18. The fine particle measurement device according to claim 17 , wherein the light detection unit includes a third spectral device configured to separate the fluorescent, and the fluorescence detection device is arranged with a plurality of independent light reception devices configured to detect the fluorescence separated by the third spectral device. 19. The fine particle measurement device according to claim 13 , wherein the arithmetic computation unit extracts only the intensity information about the fine particle where at least one of a difference Δ1 (A−C) of detection values in the area A and the area C which is not adjacent to the area A or a difference Δ2 ((A+C)−(B+D)) between a summation (A+C) of detection values in