| 释义 |
Radon TransformAn Integral Transform whose inverse is used to reconstruct images from medical CT scans. A technique for using Radontransforms to reconstruct a map of a planet's polar regions using a spacecraft in a polar orbit has also been devised(Roulston and Muhleman 1997).
The Radon transform can be defined by  | |  | (1) |
where  is the Slope of a line and  is its intercept. The inverse Radon transform is
 | (2) |
 is a Hilbert Transform. The transform can also be defined by
 | (3) |
 is the Perpendicular distance from a line to the origin and  is the Angle formed by thedistance Vector.
Using the identity
 | (4) |
 is the Fourier Transform, gives the inversion formula
 | (5) |
 | (6) |
 is a Weighting Function such as
 | (7) |
Nievergelt (1986) uses the inverse formula
 | (8) |
 | (9) |
 and  are related by
The Radon transform satisfies superposition
 | (12) |
 | (13) |
 | (14) |
 Rotation by Angle 
 | (15) |
 | (16) |
The line integral along  is
 | (17) |
 | (18) |
 | (19) |
 | (20) |
 is a continuous function on  , integrable with respect to a plane Lebesgue Measure, and
 | (21) |
 where  is the length measure, then must be identically zero. However, if theglobal integrability condition is removed, this result fails (Zalcman 1982, Goldstein 1993).See also Tomography
References
 Radon TransformsAnger, B. and Portenier, C. Radon Integrals. Boston, MA: Birkhäuser, 1992. Armitage, D. H. and Goldstein, M. ``Nonuniqueness for the Radon Transform.'' Proc. Amer. Math. Soc. 117, 175-178, 1993. Deans, S. R. The Radon Transform and Some of Its Applications. New York: Wiley, 1983. Durrani, T. S. and Bisset, D. ``The Radon Transform and its Properties.'' Geophys. 49, 1180-1187, 1984. Esser, P. D. (Ed.). Emission Computed Tomography: Current Trends. New York: Society of Nuclear Medicine, 1983. Gindikin, S. (Ed.). Applied Problems of Radon Transform. Providence, RI: Amer. Math. Soc., 1994. Gradshteyn, I. S. and Ryzhik, I. M. Tables of Integrals, Series, and Products, 5th ed. San Diego, CA: Academic Press, 1979. Helgason, S. The Radon Transform. Boston, MA: Birkhäuser, 1980. Kunyansky, L. A. ``Generalized and Attenuated Radon Transforms: Restorative Approach to the Numerical Inversion.'' Inverse Problems 8, 809-819, 1992. Nievergelt, Y. ``Elementary Inversion of Radon's Transform.'' SIAM Rev. 28, 79-84, 1986. Rann, A. G. and Katsevich, A. I. The Radon Transform and Local Tomography. Boca Raton, FL: CRC Press, 1996. Robinson, E. A. ``Spectral Approach to Geophysical Inversion Problems by Lorentz, Fourier, and Radon Transforms.'' Proc. Inst. Electr. Electron. Eng. 70, 1039-1053, 1982. Roulston, M. S. and Muhleman, D. O. ``Synthesizing Radar Maps of Polar Regions with a Doppler-Only Method.'' Appl. Opt. 36, 3912-3919, 1997. Shepp, L. A. and Kruskal, J. B. ``Computerized Tomography: The New Medical X-Ray Technology.'' Amer. Math. Monthly 85, 420-439, 1978. Strichartz, R. S. ``Radon Inversion--Variation on a Theme.'' Amer. Math. Monthly 89, 377-384 and 420-423, 1982. Zalcman, L. ``Uniqueness and Nonuniqueness for the Radon Transform.'' Bull. London Math. Soc. 14, 241-245, 1982.
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