Patent Number: 
Section: claims

1. A scanning probe microscope comprising: a driving unit for driving one of a sample and a probe microscopically in X, Y and Z directions to cause scanning movement of the one relative to the other;  a displacement detector for measuring displacement of the driving unit in the X, Y and Z directions to obtain a plurality of measurement data values in each of the three directions during the scanning movement; and  an image correction device for storing the measurement data values output by the displacement detector in the form of a data array for each of the X, Y and Z directions, performing a correction process for correcting the data arrays in the X, Y and Z directions without using calibration data obtained by scanning a specimen having a known shape, and producing an output image based on the corrected data arrays. 2. A scanning probe microscope according to  claim 1 ; wherein the correction process comprises correction of an angle of deviation of the displacement detector from an ideal angular position in at least one of the X, Y and Z directions. claim 1 3. A scanning probe microscope according to  claim 1 ; wherein the correction process comprises correcting for a drift in measurement data values output by the displacement detector with respect to time. claim 1 4. A scanning probe microscope according to  claim 1 ; further comprising a characteristic information measuring unit for measuring representing one or more characteristics of a surface of the sample simultaneously with measurement of data values output by the displacement detector in each of the X and Y directions; wherein the image correction device stores the measurement data values output by the displacement detector and output values of the characteristic information measuring unit as data arrays during the scanning and produces an output image based on the stored data arrays and the characteristic information while performing the correction process in the three directions. claim 1 5. A scanning probe microscope according to  claim 1 ; wherein the image correction device comprises a near point choosing unit for choosing one or more measurement data values having X and Y coordinates in the vicinity of those of individual points of an output image produced based on the data arrays, and a correction value calculator for performing the correction process by calculating corrected values for the data arrays constituting intensity values of the individual points of the image output from chosen near points; wherein the X and Y coordinates of the individual points of the output image correspond to displacement of the driving unit in the X and Y directions in an equally spaced manner and the intensity of the individual points corresponds to one of displacement in the Z direction of the driving unit or surface characteristic information of the sample. claim 1 6. A scanning probe microscope according to  claim 5 ; wherein the near point choosing unit chooses two or more measurement data values having X and Y coordinates closest to those of a plurality of target points in the output image. claim 5 7. A scanning probe microscope according to  claim 6 ; wherein the correction value calculator uses a Z-direction output value of the displacement detector corresponding to the measurement data values chosen by the near point choosing unit as a correction value. claim 6 8. A scanning probe microscope according to  claim 6 ; wherein the correction value calculator calculates an average value for Z displacement detector output values included in two or more groups of data chosen by the near point choosing unit as a correction value. claim 6 9. A scanning probe microscope according to  claim 5 ; wherein the near point choosing unit chooses three measurement data values in the vicinity of each of a plurality of target points in the output image from the data arrays in the X, Y and Z directions, forms the three chosen measurement data values into a triangle in an XY plane, and determines whether or not a corresponding target point is within the triangle. claim 5 10. A scanning probe microscope according to  claim 5 ; wherein the near point choosing unit divides an XY plane containing the data arrays of the displacement detector output values into groups each having three points and forming a triangle, each group including a target point of the output image on which the correction process is performed. claim 5 11. A scanning probe microscope according to  claim 10 ; wherein the correction value calculator obtains a correction value using an approximation plane formed within XYZ space from the three groups of data chosen by the near point choosing unit. claim 10 12. A scanning probe microscope according to  claim 10 ; wherein the correction calculator obtains an approximation line both passing through and linking individual points of a side and a facing side of a quadrilateral formed in XYZ space, from a group of four items of data chosen by the near point choosing unit. claim 10 13. A scanning probe microscope according to  claim 5 ; wherein the near point choosing unit chooses four measurement data values in the vicinity of each of plural target points in the output image from the data arrays of the displacement detector output values in the X, Y and Z directions, forms a quadrilateral in an XY plane using the four chosen measurement data values, and determines whether or not a respective target point is within the quadrilateral. claim 5 14. A scanning probe microscope comprising: driving means for driving one of a sample and a probe microscopically in X, Y and Z directions to cause scanning movement of the one relative to the other;  displacement detection means for measuring displacement of the driving means in the X, Y and Z directions to obtain measurement data values in each of the three directions during the scanning; and  image correction means for storing the measurement data values output by the displacement detection means in the form of a data array for each of the X, Y and Z directions, performing a correction process for correcting the data arrays in each of the X, Y and Z directions without using calibration data obtained by scanning a specimen having a known shape, and obtaining an output image based on the corrected data arrays. 15. A scanning probe microscope according to  claim 14 ; wherein the correction process comprises correction of an angle of deviation of the displacement detection means from an ideal angular position in at least one of the X, Y and Z directions. claim 14 16. A scanning probe microscope according to  claim 14 ; wherein the correction process comprises correcting for a drift in measurement data values output by the displacement detection means with respect to time. claim 14 17. A scanning probe microscope according to  claim 14 ; further comprising characteristic information measuring means for measuring information representing one or more characteristics of a surface of the sample simultaneously with measurement of data values of the displacement detection means for each of the X and Y directions; wherein the image correction means stores the measurement data values output by the displacement detection means and output values of the characteristic information measuring means as data arrays during the scanning and produces an output image based on the stored data arrays and the characteristic information while performing the correction process in the three directions. claim 14 18. A scanning probe microscope according to  claim 14 ; wherein the image correction means comprises near point choosing means for choosing one or more measurement data values having X and Y coordinates in the vicinity of those of individual points of an output image produced based on the data arrays, and correction value calculating means for performing the correction process by calculating corrected values for the data arrays constituting intensity values of the individual points of the image output from chosen near points; wherein the X and Y coordinates of the individual points of the output image correspond to displacement values of the driving means in the X and Y directions in an equally spaced manner and the intensity of the individual points corresponds to one of displacement in the Z direction of the driving means or surface characteristic information of the sample. claim 14