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{{Short description|Theorem in mathematics}}
{{technical|date=April 2025}}
[[File:Fourier Slice Theorem.png|thumb|Fourier slice theorem]]
In [[mathematics]], the '''projection-slice theorem''', '''central slice theorem''' or '''Fourier slice theorem''' in two dimensions states that the results of the following two calculations are equal:
* Take a two-dimensional function ''f''('''r'''), [[Projection (mathematics)|project]] (e.g. using the [[Radon transform]]) it onto a (one-dimensional) line, and do a [[Fourier transform]] of that projection.
* Take that same function, but do a two-dimensional Fourier transform first, and then
▲* Take that same function, but do a two-dimensional Fourier transform first, and then '''slice''' it through its origin, which is parallel to the projection line.
In operator terms, if
* ''F''<sub>1</sub> and ''F''<sub>2</sub> are the 1- and 2-dimensional Fourier transform operators mentioned above,
* ''P''<sub>1</sub> is the projection operator (which projects a 2-D function onto a 1-D line)
* ''S''<sub>1</sub> is a slice operator (which extracts a 1-D central slice from a function),
then
▲:<math>F_1 P_1=S_1 F_2\,</math>
This idea can be extended to higher dimensions.
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density of the internal organ, and these slices can be interpolated to build
up a complete Fourier transform of that density. The inverse Fourier transform
is then used to recover the 3-dimensional density of the object.
== The projection-slice theorem in ''N'' dimensions ==
In ''N'' dimensions, the
[[Fourier transform]] of the
''f''('''r''') onto an ''m''-dimensional [[Euclidean space|linear submanifold]]
is equal to an ''m''-dimensional
function consisting of an ''m''-dimensional linear submanifold through the origin in the Fourier space which is parallel to the projection submanifold. In operator terms:
:<math>F_mP_m=S_mF_N.\,</math>
==The generalized Fourier-slice theorem==
In addition to generalizing to ''N'' dimensions, the projection-slice theorem can be further generalized with an arbitrary [[change of basis]].<ref name="NgFourierSlicePhotography">{{cite journal |last = Ng |first = Ren |title = Fourier Slice Photography |journal = ACM Transactions on Graphics |year = 2005 |url = https://graphics.stanford.edu/papers/fourierphoto/fourierphoto-600dpi.pdf |volume = 24 |issue = 3 |pages = 735–744 |doi = 10.1145/1073204.1073256 }}</ref> For convenience of notation, we consider the change of basis to be represented as ''B'', an ''N''-by-''N'' [[invertible matrix]] operating on ''N''-dimensional column vectors. Then the generalized Fourier-slice theorem can be stated as
: <math>F_m P_m B = S_m \frac{B^{-T}}{|B^{-T}|} F_N</math>
where <math>B^{-T}=(B^{-1})^T</math> is the transpose of the inverse of the change of basis transform.
== Proof in two dimensions ==
[[Image:ProjectionSlice.png|frame|center
The projection-slice theorem is easily proven for the case of two dimensions.
[[Without loss of generality]], we can take the projection line to be the ''x''-axis.
There is no loss of generality because if we use a shifted and rotated line, the law still applies. Using a shifted line (in y) gives the same projection and therefore the same 1D Fourier transform results. The rotated function is the Fourier pair of the rotated Fourier transform, for which the theorem again holds.
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== The FHA cycle ==
If the two-dimensional function ''f''('''r''') is circularly symmetric, it may be represented as ''f''(''r''), where ''r'' = |'''r'''|. In this case the projection onto any projection line
will be the [[Abel transform]] of ''f''(''r''). The two-dimensional [[Fourier transform]]
of ''f''('''r''') will be a circularly symmetric function given by the zeroth
: <math>
where ''A''<sub>1</sub> represents the Abel
operator, and ''H'' represents the zeroth
== Extension to fan beam or cone-beam CT ==
The projection-slice theorem is suitable for CT image reconstruction with parallel beam projections. It does not directly apply to fanbeam or conebeam CT. The theorem was extended to fan-beam and conebeam CT image reconstruction by Shuang-ren Zhao in 1995.<ref name="ZhaoFSliceThoerem">{{cite
== See also ==
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== Further reading ==
* {{cite journal |last = Bracewell |first = Ronald N. |
* {{cite journal |last = Bracewell |first = Ronald N. |title = Strip Integration in Radio Astronomy |journal = Aust. J. Phys. |year = 1956 |volume = 9 |pages = 198 |doi = 10.1071/PH560198 |
* {{cite book |author = Gaskill, Jack D. |title = Linear Systems, Fourier Transforms, and Optics |publisher = John Wiley & Sons, New York |year = 2005 |isbn = 978-0-471-29288-
* {{cite journal |last = Ng |first = Ren |title = Fourier Slice Photography |journal = ACM Transactions on Graphics |year = 2005 |url = https://graphics.stanford.edu/papers/fourierphoto/fourierphoto-600dpi.pdf |volume = 24 |issue = 3 |pages = 735–744 |doi = 10.1145/1073204.1073256 }}
* {{cite journal |last1 = Zhao |first1 = Shuang-Ren |last2 = Halling |first2 = Horst |title = Reconstruction of Cone Beam Projections with Free Source Path by a Generalized Fourier Method |journal = Proceedings of the 1995 International Meeting on Fully Three-Dimensional Image Reconstruction in
* {{cite journal |last1 = Garces |first1 = Daissy H. |last2 = Rhodes |first2 = William T. |last3 = Peña |first3 = Néstor |title = The Projection-Slice Theorem: A Compact Notation |journal = Journal of the Optical Society of America A|year = 2011 |volume = 28 |issue = 5 |pages = 766–769 |doi = 10.1364/JOSAA.28.000766 |pmid = 21532686 |bibcode = 2011JOSAA..28..766G }}
== External links ==
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