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{{Short description|Integral transform}}
[[File:Radon transform.png|thumb|Radon transform. Maps ''f'' on the (''x,{{nbsp}}y'')-domain to ''Rf'' on the (''α,{{nbsp}}s'')-domain.|271x271px]]
[[File:Radon transform.png|thumb|upright=1.15|right|Radon transform. Maps ''f'' on the (''x'',{{nbsp}}''y'')-domain to ''Rf'' on the (''α'',{{nbsp}}''s'')-domain.]]
[[File:Sinogram - Two Square Indicator Phantom.svg|thumb|right|Radon transform of the [[indicator function]] of two squares shown in the image below. Lighter regions indicate larger function values. Black indicates zero.|399x399px]]
In [[mathematics]], the '''Radon transform''' is the [[integral transform]] which takes a function ''f'' defined on the plane to a function ''Rf'' defined on the (two-dimensional) space of lines in the plane, whose value at a particular line is equal to the [[line integral]] of the function over that line. The transform was introduced in 1917 by [[Johann Radon]],{{sfn|Radon|1917}} who also provided a formula for the inverse transform. Radon further included formulas for the transform in [[three dimensions]], in which the integral is taken over planes (integrating over lines is known as the [[X-ray transform]]). It was later generalized to higher-dimensional [[Euclidean space]]s and more broadly in the context of [[integral geometry]]. The [[complex number|complex]] analogue of the Radon transform is known as the [[Penrose transform]]. The Radon transform is widely applicable to [[tomography]], the creation of an image from the projection data associated with cross-sectional scans of an object.
[[File:Sinogram Source - Two Squares Phantom.svg|thumb|right|Original function is equal to one on the white region and zero on the dark region.|220x220px]]
In [[mathematics]], the '''Radon transform''' is the [[integral transform]] which takes a function ''f'' defined on the plane to a function ''Rf'' defined on the (two-dimensional) space of lines in the plane, whose value at a particular line is equal to the [[line integral]] of the function over that line. The transform was introduced in 1917 by [[Johann Radon]],{{sfn|Radon|1917}} who also provided a formula for the inverse transform. Radon further included formulas for the transform in [[three dimensions]], in which the integral is taken over planes (integrating over lines is known as the [[X-ray transform]]). It was later generalized to higher-dimensional [[Euclidean space]]s, and more broadly in the context of [[integral geometry]]. The [[complex number|complex]] analogue of the Radon transform is known as the [[Penrose transform]]. The Radon transform is widely applicable to [[tomography]], the creation of an image from the projection data associated with cross-sectional scans of an object.


==Explanation==
==Explanation==
[[File:Sinogram - Two Square Indicator Phantom.svg|thumb|upright=1.35|Radon transform of the [[indicator function]] of two squares shown in the image below. Lighter regions indicate larger function values. Black indicates zero.]]
If a function <math>f</math> represents an unknown density, then the Radon transform represents the projection data obtained as the output of a tomographic scan. Hence the inverse of the Radon transform can be used to reconstruct the original density from the projection data, and thus it forms the mathematical underpinning for [[tomographic reconstruction]], also known as [[iterative reconstruction]].
[[File:Sinogram Source - Two Squares Phantom.svg|thumb|right|Original function is equal to one on the white region and zero on the dark region.]]

If a function<math>f</math> represents an unknown density, then the Radon transform represents the projection data obtained as the output of a tomographic scan. Hence the inverse of the Radon transform can be used to reconstruct the original density from the projection data, and thus it forms the mathematical underpinning for [[tomographic reconstruction]], also known as [[iterative reconstruction]].
[[File:Radon transform sinogram.gif|thumb|300px|right|Horizontal projections through the shape result in an accumulated signal (middle bar). The sinogram on the right is generated by collecting many such projections as the shape rotates. Here, color is used to highlight which object is producing which part of the signal. Note how straight features, when aligned with the projection direction, result in stronger signals.]]


The Radon transform data is often called a '''sinogram''' because the Radon transform of an off-center point source is a sinusoid. Consequently, the Radon transform of a number of small objects appears graphically as a number of blurred [[sine wave]]s with different amplitudes and phases.
The Radon transform data is often called a '''sinogram''' because the Radon transform of an off-center point source is a sinusoid. Consequently, the Radon transform of a number of small objects appears graphically as a number of blurred [[sine wave]]s with different amplitudes and phases.


The Radon transform is useful in [[computed axial tomography]] (CAT scan), [[barcode]] scanners, [[electron microscopy]] of [[macromolecular assemblies]] like [[virus]]es and [[protein complex]]es, [[reflection seismology]] and in the solution of hyperbolic [[partial differential equations]].
The Radon transform is useful in [[computed axial tomography]] (CAT scan), [[barcode]] scanners, [[electron microscopy]] of [[macromolecular assemblies]] like [[virus]]es and [[protein complex]]es, [[reflection seismology]] and in the solution of hyperbolic [[partial differential equations]].[[File:Radon transform sinogram.gif|thumb|Horizontal projections through the shape result in an accumulated signal (middle bar). The sinogram on the right is generated by collecting many such projections as the shape rotates. Here, color is used to highlight which object is producing which part of the signal. Note how straight features, when aligned with the projection direction, result in stronger signals.|center|500x500px]][[File:Radon transform example.jpg|thumb|Example of reconstruction via the Radon transform using observations from different angles. The applied inversion to the projection data then reconstructs the slice image.<ref>{{Cite thesis|type=Bachelor's thesis |last=Odložilík |first=Michal |date=2023-08-31 |title=Detachment tomographic inversion study with fast visible cameras on the COMPASS tokamak |hdl=10467/111617 |language=en|publisher=Czech Technical University in Prague}}</ref>]]

{{clear}}

==Definition==
==Definition==
Let <math>f(\textbf x) = f(x,y)</math>be a function that satisfies the three regularity conditions:<ref>{{Cite journal|last=Radon|first=J.|date=December 1986|title=On the determination of functions from their integral values along certain manifolds|journal=IEEE Transactions on Medical Imaging|volume=5|issue=4|pages=170–176|doi=10.1109/TMI.1986.4307775|pmid=18244009|s2cid=26553287}}</ref>
Let <math>f(\textbf x) = f(x,y)</math> be a function that satisfies the three regularity conditions:{{sfn|Radon|1986}}


# <math>f(\textbf x)</math> is continuous;
# <math>f(\textbf x)</math> is continuous;
# the double integral <math>\iint\dfrac{\vert f(\textbf x)\vert }{\sqrt{x^2+y^2}}dx dy</math>, extending over the whole plane, converges;
# the double integral <math>\iint\dfrac{\vert f(\textbf x)\vert }{\sqrt{x^2+y^2}} \, dx \, dy</math>, extending over the whole plane, converges;
# for any arbitrary point <math>(x,y)</math> on the plane it holds that <math>\lim_{r\to\infty}\int_0^{2\pi}f(x+r\cos\phi,y+r\sin\phi)d\phi=0.</math>
# for any arbitrary point <math>(x,y)</math> on the plane it holds that <math>\lim_{r\to\infty}\int_0^{2\pi} f(x+r\cos\varphi,y+r\sin\varphi) \, d\varphi=0.</math>



The Radon transform, <math>Rf</math>, is a function defined on the space of straight lines <math>L \subset \mathbb R^2</math> by the [[Line integral#Definition|line integral]] along each such line as:<math display="block">Rf(L) = \int_L f(\mathbf{x}) \vert d\mathbf{x}\vert .</math>Concretely, the parametrization of any straight line ''<math>L</math>'' with respect to arc length <math>z</math> can always be written:<math display="block">(x(z),y(z)) = \Big( (z\sin\alpha+s\cos\alpha), (-z\cos\alpha+s\sin\alpha) \Big) \,</math>where <math>s</math> is the distance of <math>L </math> from the origin and <math>\alpha</math> is the angle the normal vector to ''<math>L</math>'' makes with the <math>X</math>-axis. It follows that the quantities <math>(\alpha,s)</math> can be considered as coordinates on the space of all lines in <math>\mathbb R^2</math>, and the Radon transform can be expressed in these coordinates by: <math display="block">\begin{align}
The Radon transform, <math>Rf</math>, is a function defined on the space of straight lines <math>L \subset \mathbb R^2</math> by the [[Line integral#Definition|line integral]] along each such line as:
<math display="block">Rf(L) = \int_L f(\mathbf{x}) \vert d\mathbf{x}\vert .</math>Concretely, the parametrization of any straight line ''<math>L</math>'' with respect to arc length <math>z</math> can always be written:<math display="block">(x(z),y(z)) = \Big( (z\sin\alpha+s\cos\alpha), (-z \cos\alpha + s\sin\alpha) \Big) \,</math>where <math>s</math> is the distance of <math>L </math> from the origin and <math>\alpha</math> is the angle the normal vector to ''<math>L</math>'' makes with the <math>X</math>-axis. It follows that the quantities <math>(\alpha,s)</math> can be considered as coordinates on the space of all lines in <math>\mathbb R^2</math>, and the Radon transform can be expressed in these coordinates by: <math display="block">\begin{align}
Rf(\alpha,s)
Rf(\alpha,s)
&= \int_{-\infty}^{\infty} f(x(z),y(z)) dz\\
&= \int_{-\infty}^\infty f(x(z),y(z)) \, dz\\
&= \int_{-\infty}^{\infty} f\big( (z\sin\alpha+s\cos\alpha), (-z\cos\alpha+s\sin\alpha) \big) dz
&= \int_{-\infty}^\infty f\big( (z\sin\alpha+s\cos\alpha), (-z\cos\alpha+s\sin\alpha) \big) \, dz.
\end{align}.</math>More generally, in the <math>n</math>-dimensional [[Euclidean space]] <math>\mathbb R^n</math>, the Radon transform of a function <math>f</math> satisfying the regularity conditions is a function ''<math>Rf</math>'' on the space <math>\Sigma_n</math> of all [[hyperplane]]s in <math>\mathbb R^n</math>. It is defined by:
\end{align}</math>More generally, in the <math>n</math>-dimensional [[Euclidean space]] <math>\mathbb R^n</math>, the Radon transform of a function <math>f</math> satisfying the regularity conditions is a function ''<math>Rf</math>'' on the space <math>\Sigma_n</math> of all [[hyperplane]]s in <math>\mathbb R^n</math>. It is defined by:


{{multiple image
{{multiple image
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| direction = horizontal
| direction = horizontal
| image1 = SheppLogan_Phantom.svg
| image1 = SheppLogan_Phantom.svg
| width1 = 170
| caption1 = [[Shepp-Logan Phantom|Shepp Logan phantom]]
| caption1 = [[Shepp-Logan Phantom|Shepp Logan phantom]]
| image2 = Shepp logan radon.png
| image2 = Shepp logan radon.png
| width2 = 42
| caption2 = Radon transform
| caption2 = Radon transform
| image3 = Shepp logan iradon.png
| image3 = Shepp logan iradon.png
| width3 = 170
| caption3 = Inverse Radon transform
| caption3 = Inverse Radon transform
| total_width = 400
| total_width = 400
| alt1 =
}}
}}


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{{main|Projection-slice theorem}}
{{main|Projection-slice theorem}}


[[File:Radon transform via Fourier transform.png|thumb|Computing the 2-dimensional Radon transform in terms of two Fourier transforms.|1000x1000px]]
[[File:Radon transform via Fourier transform.png|thumb|Computing the 2-dimensional Radon transform in terms of two Fourier transforms.|1000x1000px|none]]


The Radon transform is closely related to the [[Fourier transform]]. We define the univariate Fourier transform here as: <math display="block">\hat{f}(\omega)=\int_{-\infty}^\infty f(x)e^{-2\pi ix\omega }\,dx.
The Radon transform is closely related to the [[Fourier transform]]. We define the univariate Fourier transform here as: <math display="block">\hat{f}(\omega)=\int_{-\infty}^\infty f(x)e^{-2\pi ix\omega }\,dx.
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</math> where <math>\mathbf{n}(\alpha)= (\cos \alpha,\sin\alpha).</math>
</math> where <math>\mathbf{n}(\alpha)= (\cos \alpha,\sin\alpha).</math>


Thus the two-dimensional Fourier transform of the initial function along a line at the inclination angle <math>\alpha</math> is the one variable Fourier transform of the Radon transform (acquired at angle <math>\alpha</math>) of that function. This fact can be used to compute both the Radon transform and its inverse. The result can be generalized into ''n'' dimensions: <math display="block">\hat{f}(r\alpha) = \int_{\mathbb R}\mathcal{R}f(\alpha,s)e^{-2\pi i sr} ds.</math>
Thus the two-dimensional Fourier transform of the initial function along a line at the inclination angle <math>\alpha</math> is the one variable Fourier transform of the Radon transform (acquired at angle <math>\alpha</math>) of that function. This fact can be used to compute both the Radon transform and its inverse. The result can be generalized into ''n'' dimensions: <math display="block">\hat{f}(r\alpha) = \int_{\mathbb R}\mathcal{R}f(\alpha,s)e^{-2\pi i sr} \, ds.</math>


== Dual transform ==
== Dual transform ==
The dual Radon transform is a kind of [[Hermitian adjoint|adjoint]] to the Radon transform. Beginning with a function ''g'' on the space <math>\Sigma_n</math>, the dual Radon transform is the function <math>\mathcal{R}^*g</math> on '''R'''<sup>''n''</sup> defined by: <math display="block">\mathcal{R}^*g(x) = \int_{x\in\xi} g(\xi)\,d\mu(\xi).</math>The integral here is taken over the set of all hyperplanes incident with the point <math>\textbf x \in \mathbb R^n</math>, and the measure <math>d \mu</math> is the unique [[probability measure]] on the set <math>\{\xi | x\in\xi\}</math> invariant under rotations about the point <math>x</math>.
The dual Radon transform is a kind of [[Hermitian adjoint|adjoint]] to the Radon transform. Beginning with a function ''g'' on the space <math>\Sigma_n</math>, the dual Radon transform is the function <math>\mathcal{R}^*g</math> on '''R'''<sup>''n''</sup> defined by: <math display="block">\mathcal{R}^*g(\mathbf{x}) = \int_{\mathbf{x}\in\xi} g(\xi)\,d\mu(\xi).</math>The integral here is taken over the set of all hyperplanes incident with the point <math>\textbf x \in \mathbb R^n</math>, and the measure <math>d \mu</math> is the unique [[probability measure]] on the set <math>\{\xi | \mathbf{x}\in\xi\}</math> invariant under rotations about the point <math>\mathbf{x}</math>.


Concretely, for the two-dimensional Radon transform, the dual transform is given by: <math display="block">\mathcal{R}^*g(x) = \frac{1}{2\pi}\int_{\alpha=0}^{2\pi}g(\alpha,\mathbf{n}(\alpha)\cdot\mathbf{x})\,d\alpha.</math> In the context of image processing, the dual transform is commonly called ''back-projection''{{sfn|Roerdink|2001}} as it takes a function defined on each line in the plane and 'smears' or projects it back over the line to produce an image.
Concretely, for the two-dimensional Radon transform, the dual transform is given by: <math display="block">\mathcal{R}^*g(\mathbf{x}) = \frac{1}{2\pi}\int_{\alpha=0}^{2\pi}g(\alpha,\mathbf{n}(\alpha)\cdot\mathbf{x})\,d\alpha.</math> In the context of image processing, the dual transform is commonly called ''back-projection''{{sfn|Roerdink|2001}} as it takes a function defined on each line in the plane and 'smears' or projects it back over the line to produce an image.


===Intertwining property===
===Intertwining property===
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|last4 = Pfister|first4= H.
|last4 = Pfister|first4= H.
|title= Sliced and Radon Wasserstein Barycenters of Measures
|title= Sliced and Radon Wasserstein Barycenters of Measures
|journal= Journal of Mathematical Imaging and Vision|date=2015|volume=51|number=1|pages=22–25 |doi=10.1007/s10851-014-0506-3|s2cid= 1907942
|journal= Journal of Mathematical Imaging and Vision|date=2015|volume=51|number=1|pages=22–25 |doi=10.1007/s10851-014-0506-3|bibcode= 2015JMIV...51...22B
|s2cid= 1907942
|url= http://hal.archives-ouvertes.fr/hal-00881872
|url= http://hal.archives-ouvertes.fr/hal-00881872
}}</ref> and numerical analysis<ref>{{cite journal|last = Rim|first= D.|title=Dimensional Splitting of Hyperbolic Partial Differential Equations Using the Radon Transform
}}</ref> and numerical analysis<ref>{{cite journal|last = Rim|first= D.|title=Dimensional Splitting of Hyperbolic Partial Differential Equations Using the Radon Transform
|journal= SIAM J. Sci. Comput.|date= 2018|volume= 40|number= 6 |pages=A4184–A4207|doi=10.1137/17m1135633|arxiv= 1705.03609|s2cid= 115193737}}</ref> this is exploited to reduce multi-dimensional problems into single-dimensional ones, as a dimensional splitting method.
|journal= SIAM J. Sci. Comput.|date= 2018|volume= 40|number= 6 |pages=A4184–A4207|doi=10.1137/17m1135633|arxiv= 1705.03609|bibcode= 2018SJSC...40A4184R|s2cid= 115193737}}</ref> this is exploited to reduce multi-dimensional problems into single-dimensional ones, as a dimensional splitting method.


==Reconstruction approaches==
==Reconstruction approaches==
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===Radon inversion formula===
===Radon inversion formula===
In the two dimensional case, the most commonly used analytical formula to recover <math>f</math> from its Radon transform is the ''Filtered Back-projection Formula'' or ''Radon Inversion Formula{{sfn|Candès|2016b}}'': <math display="block">f(\mathbf{x})=\int^{\pi}_{0}(\mathcal{R}f(\cdot,\theta)*h)(\left\langle\mathbf{x},\mathbf{n}_{\theta} \right\rangle) d\theta</math>where <math>h</math> is such that <math>\hat{h}(k)=|k|</math>.{{sfn|Candès|2016b}} The convolution kernel <math>h</math> is referred to as Ramp filter in some literature.
In the two-dimensional case, the most commonly used analytical formula to recover <math>f</math> from its Radon transform is the ''Filtered Back-projection Formula'' or ''Radon Inversion Formula{{sfn|Candès|2016b}}'': <math display="block">f(\mathbf{x})=\int^\pi_0 (\mathcal{R}f(\cdot,\theta)*h)(\left\langle\mathbf{x},\mathbf{n}_\theta \right\rangle) \, d\theta</math>where <math>h</math> is such that <math>\hat{h}(k)=|k|</math>.{{sfn|Candès|2016b}} The convolution kernel <math>h</math> is referred to as Ramp filter in some literature.


===Ill-posedness===
===Ill-posedness===
Intuitively, in the ''filtered back-projection'' formula, by analogy with differentiation, for which <math>\left(\widehat{\frac{d}{dx}f}\right)\!(k)=ik\widehat{f}(k)</math>, we see that the filter performs an operation similar to a derivative. Roughly speaking, then, the filter makes objects ''more'' singular. A quantitive statement of the ill-posedness of Radon Inversion goes as follows:<math display="block">\widehat{\mathcal{R}^*\mathcal{R}g}(k)=\frac{1}{||\mathbf{k}||}\hat{g}(\mathbf{k})</math>where <math>\mathcal{R}^*</math> is the previously defined [[adjoint]] to the Radon Transform. Thus for <math>g(\mathbf{x})=e^{i \left\langle\mathbf{k}_0,\mathbf{x}\right\rangle}</math>, we have: <math display="block"> \mathcal{R}^*\mathcal{R}g=\frac{1}{||\mathbf{k_0}||}e^{i \left\langle\mathbf{k}_0,\mathbf{x}\right\rangle}</math>The complex exponential <math>e^{i \left\langle\mathbf{k}_0,\mathbf{x}\right\rangle}</math> is thus an eigenfunction of <math>\mathcal{R}^*\mathcal{R}</math> with eigenvalue <math>\frac{1}{||\mathbf{k_0}||}</math>. Thus the singular values of <math>\mathcal{R}</math> are <math>\sqrt{\frac{1}{||\mathbf{k}||}}</math>. Since these singular values tend to <math>0</math>, <math>\mathcal{R}^{-1}</math> is unbounded.{{sfn|Candès|2016b}}
Intuitively, in the ''filtered back-projection'' formula, by analogy with differentiation, for which <math display="inline">\left(\widehat{\frac{d}{dx}f}\right)\!(k)=ik\widehat{f}(k)</math>, we see that the filter performs an operation similar to a derivative. Roughly speaking, then, the filter makes objects ''more'' singular. A quantitive statement of the ill-posedness of Radon inversion goes as follows:<math display="block">\widehat{\mathcal{R}^*\mathcal{R} [g]}(\mathbf{k}) = \frac{1}{\|\mathbf{k}\|} \hat{g}(\mathbf{k})</math>
where <math>\mathcal{R}^*</math> is the previously defined adjoint to the Radon transform. Thus for <math>g(\mathbf{x}) = e^{i \left\langle\mathbf{k}_0,\mathbf{x}\right\rangle}</math>, we have: <math display="block"> \mathcal{R}^*\mathcal{R}[g](\mathbf{x}) = \frac{1}{\|\mathbf{k_0}\|} e^{i \left\langle\mathbf{k}_0,\mathbf{x}\right\rangle}</math>
The complex exponential <math>e^{i \left\langle\mathbf{k}_0,\mathbf{x}\right\rangle}</math> is thus an eigenfunction of <math>\mathcal{R}^*\mathcal{R}</math> with eigenvalue <math display="inline">\frac{1}{\|\mathbf{k}_0\|}</math>. Thus the singular values of <math>\mathcal{R}</math> are <math display="inline">\frac{1}\sqrt{\|\mathbf{k}\|}</math>. Since these singular values tend to <math>0</math>, <math>\mathcal{R}^{-1}</math> is unbounded.{{sfn|Candès|2016b}}


===Iterative reconstruction methods===
===Iterative reconstruction methods===
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==Inversion formulas==
==Inversion formulas==


Explicit and computationally efficient inversion formulas for the Radon transform and its dual are available. The Radon transform in <math>n</math> dimensions can be inverted by the formula:{{sfn|Helgason|1984|loc=Theorem I.2.13}} <math display="block">c_n f = (-\Delta)^{(n-1)/2}R^*Rf\,</math>where <math>c_n = (4\pi)^{(n-1)/2}\frac{\Gamma(n/2)}{\Gamma(1/2)}</math>, and the power of the Laplacian <math>(-\Delta)^{(n-1)/2}</math> is defined as a [[pseudodifferential operator|pseudo-differential operator]] if necessary by the [[Fourier transform]]: <math display="block">\left[\mathcal{F}(-\Delta)^{(n-1)/2}\phi\right](\xi) = |2\pi\xi|^{n-1}(\mathcal{F}\phi)(\xi).</math>For computational purposes, the power of the Laplacian is commuted with the dual transform <math>R^*</math> to give:{{sfn|Helgason|1984|loc=Theorem I.2.16}} <math display="block">c_nf = \begin{cases}
Explicit and computationally efficient inversion formulas for the Radon transform and its dual are available. The Radon transform in <math>n</math> dimensions can be inverted by the formula:{{sfn|Helgason|1984|loc=Theorem I.2.13}} <math display="block">c_n f = (-\Delta)^{(n-1)/2}R^*Rf\,</math>where <math>c_n = (4\pi)^{(n-1)/2}\frac{\Gamma(n/2)}{\Gamma(1/2)}</math>, and the power of the Laplacian <math>(-\Delta)^{(n-1)/2}</math> is defined as a [[pseudodifferential operator|pseudo-differential operator]] if necessary by the [[Fourier transform]]: <math display="block">\left[\mathcal{F}(-\Delta)^{(n-1)/2} \varphi\right](\xi) = |2\pi\xi|^{n-1}(\mathcal{F}\varphi)(\xi).</math>For computational purposes, the power of the Laplacian is commuted with the dual transform <math>R^*</math> to give:{{sfn|Helgason|1984|loc=Theorem I.2.16}} <math display="block">c_nf = \begin{cases}
R^*\frac{d^{n-1}}{ds^{n-1}}Rf & n \rm{\ odd}\\
R^*\frac{d^{n-1}}{ds^{n-1}}Rf & n \text{ odd}\\
R^* \mathcal H_s\frac{d^{n-1}}{ds^{n-1}}Rf & n \rm{\ even}
R^* \mathcal H_s\frac{d^{n-1}}{ds^{n-1}}Rf & n \text{ even}
\end{cases}
\end{cases}
</math>where <math>\mathcal H_s</math> is the [[Hilbert transform]] with respect to the ''s'' variable. In two dimensions, the operator <math>\mathcal H_s\frac{d}{ds}
</math>where <math>\mathcal H_s</math> is the [[Hilbert transform]] with respect to the ''s'' variable. In two dimensions, the operator <math>\mathcal H_s\frac{d}{ds}
</math> appears in image processing as a [[ramp filter]].{{sfn|Nygren|1997}} One can prove directly from the Fourier slice theorem and change of variables for integration that for a compactly supported continuous function <math>f
</math> appears in image processing as a [[ramp filter]].{{sfn|Nygren|1997}} One can prove directly from the Fourier slice theorem and change of variables for integration that for a compactly supported continuous function <math>f
</math> of two variables: <math display="block">f = \frac{1}{2}R^{*}H_s\frac{d}{ds}Rf.</math>Thus in an image processing context the original image <math>f
</math> of two variables: <math display="block">f = \frac{1}{2}R^{*}\mathcal H_s\frac{d}{ds}Rf.</math>Thus in an image processing context the original image <math>f
</math> can be recovered from the 'sinogram' data <math>Rf
</math> can be recovered from the 'sinogram' data <math>Rf
</math> by applying a ramp filter (in the <math>s</math> variable) and then back-projecting. As the filtering step can be performed efficiently (for example using [[digital signal processing]] techniques) and the back projection step is simply an accumulation of values in the pixels of the image, this results in a highly efficient, and hence widely used, algorithm.
</math> by applying a ramp filter (in the <math>s</math> variable) and then back-projecting. As the filtering step can be performed efficiently (for example using [[digital signal processing]] techniques) and the back projection step is simply an accumulation of values in the pixels of the image, this results in a highly efficient, and hence widely used, algorithm.
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\begin{cases}
\begin{cases}
\displaystyle - \imath 2\pi (2\pi)^{-n}(-1)^{n/2}\int_{S^{n-1}}\frac{\partial^{n-1}}{2\partial s^{n-1}}Rf(\alpha,\alpha\cdot x)\,d\alpha & n \text{ odd} \\
\displaystyle - \imath 2\pi (2\pi)^{-n}(-1)^{n/2}\int_{S^{n-1}}\frac{\partial^{n-1}}{2\partial s^{n-1}}Rf(\alpha,\alpha\cdot x)\,d\alpha & n \text{ odd} \\
\displaystyle (2\pi)^{-n}(-1)^{n/2}\iint_{\mathbb R \times S^{n-1}}\frac{\partial^{n-1}}{q\partial s^{n-1}}Rf(\alpha,\alpha\cdot x + q)\,d\alpha\,dq & n \text{ even} \\
\displaystyle (2\pi)^{-n}(-1)^{n/2}\iint_{\mathbb R \times S^{n-1}}\frac{\partial^{n-1}}{q\partial s^{n-1}} Rf(\alpha,\alpha\cdot x + q)\,d\alpha\,dq & n \text{ even} \\
\end{cases}</math>The dual transform can also be inverted by an analogous formula: <math display="block">c_n g = (-L)^{(n-1)/2}R(R^*g).\,</math>
\end{cases}</math>The dual transform can also be inverted by an analogous formula: <math display="block">c_n g = (-L)^{(n-1)/2}R(R^*g).\,</math>


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Write
Write


:<math>\mathbf P^d \stackrel{p_1} \gets H \stackrel{p_2}\to \mathbf P^{\vee, d}</math>
:<math>\mathbf P^d \, \stackrel{p_1} \gets \, H \, \stackrel{p_2}\to \, \mathbf P^{\vee, d}</math>


for the [[incidence relation|universal hyperplane]], i.e., ''H'' consists of pairs (''x'', ''h'') where ''x'' is a point in ''d''-dimensional [[projective space]] <math>\mathbf P^d</math> and ''h'' is a point in the [[dual projective space]] (in other words, ''x'' is a line through the origin in (''d''+1)-dimensional [[affine space]], and ''h'' is a hyperplane in that space) such that ''x'' is contained in ''h''.
for the [[incidence relation|universal hyperplane]], i.e., ''H'' consists of pairs (''x'', ''h'') where ''x'' is a point in ''d''-dimensional [[projective space]] <math>\mathbf P^d</math> and ''h'' is a point in the [[dual projective space]] (in other words, ''x'' is a line through the origin in (''d''+1)-dimensional [[affine space]], and ''h'' is a hyperplane in that space) such that ''x'' is contained in ''h''.


Then the Brylinksi–Radon transform is the functor between appropriate [[derived category|derived categories]] of [[étale sheaf|étale sheaves]]
Then the Brylinksi–Radon transform is the [[functor]] between appropriate [[derived category|derived categories]] of [[étale sheaf|étale sheaves]]


:<math>Rad := Rp_{2,*} p_1^* : D(\mathbf P^d) \to D(\mathbf P^{\vee, d}).</math>
:<math> \operatorname{Rad} := Rp_{2,*} p_1^* : D(\mathbf P^d) \to D(\mathbf P^{\vee, d}).</math>


The main theorem about this transform is that this transform induces an [[equivalence of categories|equivalence]] of the categories of [[perverse sheaf|perverse sheaves]] on the projective space and its dual projective space, up to constant sheaves.<ref>{{harvtxt|Kiehl|Weissauer|2001|loc=Ch. IV, Cor. 2.4}}</ref>
The main theorem about this transform is that this transform induces an [[equivalence of categories|equivalence]] of the categories of [[perverse sheaf|perverse sheaves]] on the projective space and its dual projective space, up to constant sheaves.<ref>{{harvtxt|Kiehl|Weissauer|2001|loc=Ch. IV, Cor. 2.4}}</ref>
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* [[Funk transform]]
* [[Funk transform]]
* The [[Hough transform]], when written in a continuous form, is very similar, if not equivalent, to the Radon transform.{{sfn|van Ginkel|Hendricks|van Vliet|2004}}
* The [[Hough transform]], when written in a continuous form, is very similar, if not equivalent, to the Radon transform.{{sfn|van Ginkel|Hendricks|van Vliet|2004}}
* [[Crofton formula|Cauchy-Crofton theorem]] is a closely related formula for computing the length of curves in space.
* [[Crofton formula|Cauchy–Crofton theorem]] is a closely related formula for computing the length of curves in space.
* [[Fast Fourier transform]]
* [[Fast Fourier transform]]


Line 140: Line 137:


==References==
==References==
{{sfn whitelist |CITEREFRoerdink2001}}
{{refbegin}}
{{refbegin}}
* {{Citation |author-link1=Reinhardt Kiehl |last1=Kiehl |first1=Reinhardt |last2=Weissauer |first2=Rainer |isbn=3-540-41457-6 |title=Weil conjectures, perverse sheaves and l'adic Fourier transform |publisher=Springer |year=2001 |mr=1855066 |doi=10.1007/978-3-662-04576-3 |doi-access=}}
* {{citation |title = Über die Bestimmung von Funktionen durch ihre Integralwerte längs gewisser Mannigfaltigkeiten |last = Radon |first = Johann |author-link = Johann Radon |journal = Berichte über die Verhandlungen der Königlich-Sächsischen Akademie der Wissenschaften zu Leipzig, Mathematisch-Physische Klasse [Reports on the Proceedings of the Royal Saxonian Academy of Sciences at Leipzig, Mathematical and Physical Section] |location = Leipzig |publisher = Teubner |year = 1917 |issue = 69 |pages = 262–277 }}; ''Translation:'' {{citation |title = On the determination of functions from their integral values along certain manifolds |journal = IEEE Transactions on Medical Imaging |year = 1986 |volume = 5 |pages = 170–176 |author = Radon, J. |author2 = Parks, P.C. (translator) |doi = 10.1109/TMI.1986.4307775 |pmid = 18244009 |issue = 4 |s2cid = 26553287 }}.
* {{citation |title=Über die Bestimmung von Funktionen durch ihre Integralwerte längs gewisser Mannigfaltigkeiten |last=Radon |first=Johann |author-link=Johann Radon |journal=Berichte über die Verhandlungen der Königlich-Sächsischen Akademie der Wissenschaften zu Leipzig, Mathematisch-Physische Klasse [Reports on the Proceedings of the Royal Saxonian Academy of Sciences at Leipzig, Mathematical and Physical Section] |location=Leipzig |publisher=Teubner |year=1917 |issue=69 |pages=262–277}};<br/>'''Translation:''' {{citation |title=On the determination of functions from their integral values along certain manifolds |journal=IEEE Transactions on Medical Imaging |date=December 1986 |volume=5 |issue=4 |pages=170–176 |last=Radon |first=J. |translator=Parks, P.C. |doi=10.1109/TMI.1986.4307775 |pmid=18244009 |s2cid=26553287}}.
* {{springer|id=t/t092980|title=Tomography|first=J.B.T.M.|last=Roerdink}}.
* {{springer|id=t/t092980|title=Tomography|first=J.B.T.M. |last=Roerdink }}.
* {{citation |first = Sigurdur |last = Helgason |author-link = Sigurður Helgason (mathematician) |title = Groups and Geometric Analysis: Integral Geometry, Invariant Differential Operators, and Spherical Functions |year = 1984 |publisher = Academic Press |isbn = 0-12-338301-3 |url-access = registration |url = https://archive.org/details/groupsgeometrica0000helg }}.
* {{citation |first = Sigurdur |last = Helgason |author-link = Sigurður Helgason (mathematician) |title = Groups and Geometric Analysis: Integral Geometry, Invariant Differential Operators, and Spherical Functions |year = 1984 |publisher = Academic Press |isbn = 0-12-338301-3 |url-access = registration |url = https://archive.org/details/groupsgeometrica0000helg }}.
* {{cite web |title = Applied Fourier Analysis and Elements of Modern Signal Processing - Lecture 9 |last1 = Candès |first1 = Emmanuel |url = http://statweb.stanford.edu/~candes/teaching/math262/Lectures/Lecture09.pdf |date = February 2, 2016a }}
* {{cite web |title = Applied Fourier Analysis and Elements of Modern Signal Processing Lecture 9 |last1 = Candès |first1 = Emmanuel |url = http://statweb.stanford.edu/~candes/teaching/math262/Lectures/Lecture09.pdf |date = February 2, 2016a |ref=none }}
* {{cite web |title = Applied Fourier Analysis and Elements of Modern Signal Processing - Lecture 10 |last1 = Candès |first1 = Emmanuel |url = http://statweb.stanford.edu/~candes/teaching/math262/Lectures/Lecture10.pdf |date = February 4, 2016b }}
* {{cite web |title = Applied Fourier Analysis and Elements of Modern Signal Processing Lecture 10 |last1 = Candès |first1 = Emmanuel |url = http://statweb.stanford.edu/~candes/teaching/math262/Lectures/Lecture10.pdf |date = February 4, 2016b }}
* {{cite web |url = http://www.owlnet.rice.edu/~elec539/Projects97/cult/node2.html |title = Filtered Back Projection |work = Tomographic Reconstruction of SPECT Data |last = Nygren |first = Anders J. |year = 1997 }}
* {{cite web |url = http://www.owlnet.rice.edu/~elec539/Projects97/cult/node2.html |title = Filtered Back Projection |work = Tomographic Reconstruction of SPECT Data |last = Nygren |first = Anders J. |year = 1997 }}
* {{cite web |title = A short introduction to the Radon and Hough transforms and how they relate to each other |last1 = van Ginkel |first1 = M. |last2 = Hendricks |first2 = C.L. Luengo |last3 = van Vliet |first3 = L.J. |year = 2004 |url = http://tnw.home.tudelft.nl/fileadmin/Faculteit/TNW/Over_de_faculteit/Afdelingen/Imaging_Science_and_Technology/Research/Research_Groups/Quantitative_Imaging/Publications/Technical_Reports/doc/mvanginkel_radonandhough_tr2004.pdf |archive-url = https://web.archive.org/web/20160729172119/http://tnw.home.tudelft.nl/fileadmin/Faculteit/TNW/Over_de_faculteit/Afdelingen/Imaging_Science_and_Technology/Research/Research_Groups/Quantitative_Imaging/Publications/Technical_Reports/doc/mvanginkel_radonandhough_tr2004.pdf |archive-date = 2016-07-29 |url-status = live }}
* {{cite web |title = A short introduction to the Radon and Hough transforms and how they relate to each other |last1 = van Ginkel |first1 = M. |last2 = Hendricks |first2 = C.L. Luengo |last3 = van Vliet |first3 = L.J. |year = 2004 |url = http://tnw.home.tudelft.nl/fileadmin/Faculteit/TNW/Over_de_faculteit/Afdelingen/Imaging_Science_and_Technology/Research/Research_Groups/Quantitative_Imaging/Publications/Technical_Reports/doc/mvanginkel_radonandhough_tr2004.pdf |archive-url = https://web.archive.org/web/20160729172119/http://tnw.home.tudelft.nl/fileadmin/Faculteit/TNW/Over_de_faculteit/Afdelingen/Imaging_Science_and_Technology/Research/Research_Groups/Quantitative_Imaging/Publications/Technical_Reports/doc/mvanginkel_radonandhough_tr2004.pdf |archive-date = 2016-07-29 |url-status = live }}
Line 158: Line 157:
* {{citation |first = Frank |last = Natterer |title = The Mathematics of Computerized Tomography |series = Classics in Applied Mathematics |volume = 32 |publisher = Society for Industrial and Applied Mathematics |isbn = 0-89871-493-1 |date = June 2001 }}
* {{citation |first = Frank |last = Natterer |title = The Mathematics of Computerized Tomography |series = Classics in Applied Mathematics |volume = 32 |publisher = Society for Industrial and Applied Mathematics |isbn = 0-89871-493-1 |date = June 2001 }}
* {{citation |first1 = Frank |last1 = Natterer |first2 = Frank |last2 = Wübbeling |title = Mathematical Methods in Image Reconstruction |publisher = Society for Industrial and Applied Mathematics |isbn = 0-89871-472-9 |year = 2001 }}
* {{citation |first1 = Frank |last1 = Natterer |first2 = Frank |last2 = Wübbeling |title = Mathematical Methods in Image Reconstruction |publisher = Society for Industrial and Applied Mathematics |isbn = 0-89871-472-9 |year = 2001 }}
* {{Citation|authorlink1=Reinhardt Kiehl|last1=Kiehl|first1=Reinhardt|last2=Weissauer|first2=Rainer|
isbn=3-540-41457-6
|title=Weil conjectures, perverse sheaves and l'adic Fourier transform|publisher=Springer|year=2001|mr=1855066|doi=10.1007/978-3-662-04576-3|doi-access=free}}


==External links==
==External links==
Line 168: Line 164:
[[Category:Integral geometry]]
[[Category:Integral geometry]]
[[Category:Integral transforms]]
[[Category:Integral transforms]]
[[Category:Tomography]]

Latest revision as of 10:00, 8 October 2024

Radon transform. Maps f on the (x, y)-domain to Rf on the (α, s)-domain.

In mathematics, the Radon transform is the integral transform which takes a function f defined on the plane to a function Rf defined on the (two-dimensional) space of lines in the plane, whose value at a particular line is equal to the line integral of the function over that line. The transform was introduced in 1917 by Johann Radon,[1] who also provided a formula for the inverse transform. Radon further included formulas for the transform in three dimensions, in which the integral is taken over planes (integrating over lines is known as the X-ray transform). It was later generalized to higher-dimensional Euclidean spaces and more broadly in the context of integral geometry. The complex analogue of the Radon transform is known as the Penrose transform. The Radon transform is widely applicable to tomography, the creation of an image from the projection data associated with cross-sectional scans of an object.

Explanation

[edit]
Radon transform of the indicator function of two squares shown in the image below. Lighter regions indicate larger function values. Black indicates zero.
Original function is equal to one on the white region and zero on the dark region.

If a function represents an unknown density, then the Radon transform represents the projection data obtained as the output of a tomographic scan. Hence the inverse of the Radon transform can be used to reconstruct the original density from the projection data, and thus it forms the mathematical underpinning for tomographic reconstruction, also known as iterative reconstruction.

The Radon transform data is often called a sinogram because the Radon transform of an off-center point source is a sinusoid. Consequently, the Radon transform of a number of small objects appears graphically as a number of blurred sine waves with different amplitudes and phases.

The Radon transform is useful in computed axial tomography (CAT scan), barcode scanners, electron microscopy of macromolecular assemblies like viruses and protein complexes, reflection seismology and in the solution of hyperbolic partial differential equations.

Horizontal projections through the shape result in an accumulated signal (middle bar). The sinogram on the right is generated by collecting many such projections as the shape rotates. Here, color is used to highlight which object is producing which part of the signal. Note how straight features, when aligned with the projection direction, result in stronger signals.
Example of reconstruction via the Radon transform using observations from different angles. The applied inversion to the projection data then reconstructs the slice image.[2]

Definition

[edit]

Let be a function that satisfies the three regularity conditions:[3]

  1. is continuous;
  2. the double integral , extending over the whole plane, converges;
  3. for any arbitrary point on the plane it holds that


The Radon transform, , is a function defined on the space of straight lines by the line integral along each such line as: Concretely, the parametrization of any straight line with respect to arc length can always be written:where is the distance of from the origin and is the angle the normal vector to makes with the -axis. It follows that the quantities can be considered as coordinates on the space of all lines in , and the Radon transform can be expressed in these coordinates by: More generally, in the -dimensional Euclidean space , the Radon transform of a function satisfying the regularity conditions is a function on the space of all hyperplanes in . It is defined by:

Radon transform
Inverse Radon transform

where the integral is taken with respect to the natural hypersurface measure, (generalizing the term from the -dimensional case). Observe that any element of is characterized as the solution locus of an equation , where is a unit vector and . Thus the -dimensional Radon transform may be rewritten as a function on via: It is also possible to generalize the Radon transform still further by integrating instead over -dimensional affine subspaces of . The X-ray transform is the most widely used special case of this construction, and is obtained by integrating over straight lines.

Relationship with the Fourier transform

[edit]
Computing the 2-dimensional Radon transform in terms of two Fourier transforms.

The Radon transform is closely related to the Fourier transform. We define the univariate Fourier transform here as: For a function of a -vector , the univariate Fourier transform is: For convenience, denote . The Fourier slice theorem then states: where

Thus the two-dimensional Fourier transform of the initial function along a line at the inclination angle is the one variable Fourier transform of the Radon transform (acquired at angle ) of that function. This fact can be used to compute both the Radon transform and its inverse. The result can be generalized into n dimensions:

Dual transform

[edit]

The dual Radon transform is a kind of adjoint to the Radon transform. Beginning with a function g on the space , the dual Radon transform is the function on Rn defined by: The integral here is taken over the set of all hyperplanes incident with the point , and the measure is the unique probability measure on the set invariant under rotations about the point .

Concretely, for the two-dimensional Radon transform, the dual transform is given by: In the context of image processing, the dual transform is commonly called back-projection[4] as it takes a function defined on each line in the plane and 'smears' or projects it back over the line to produce an image.

Intertwining property

[edit]

Let denote the Laplacian on defined by:This is a natural rotationally invariant second-order differential operator. On , the "radial" second derivative is also rotationally invariant. The Radon transform and its dual are intertwining operators for these two differential operators in the sense that:[5] In analysing the solutions to the wave equation in multiple spatial dimensions, the intertwining property leads to the translational representation of Lax and Philips.[6] In imaging[7] and numerical analysis[8] this is exploited to reduce multi-dimensional problems into single-dimensional ones, as a dimensional splitting method.

Reconstruction approaches

[edit]

The process of reconstruction produces the image (or function in the previous section) from its projection data. Reconstruction is an inverse problem.

Radon inversion formula

[edit]

In the two-dimensional case, the most commonly used analytical formula to recover from its Radon transform is the Filtered Back-projection Formula or Radon Inversion Formula[9]: where is such that .[9] The convolution kernel is referred to as Ramp filter in some literature.

Ill-posedness

[edit]

Intuitively, in the filtered back-projection formula, by analogy with differentiation, for which , we see that the filter performs an operation similar to a derivative. Roughly speaking, then, the filter makes objects more singular. A quantitive statement of the ill-posedness of Radon inversion goes as follows: where is the previously defined adjoint to the Radon transform. Thus for , we have: The complex exponential is thus an eigenfunction of with eigenvalue . Thus the singular values of are . Since these singular values tend to , is unbounded.[9]

Iterative reconstruction methods

[edit]

Compared with the Filtered Back-projection method, iterative reconstruction costs large computation time, limiting its practical use. However, due to the ill-posedness of Radon Inversion, the Filtered Back-projection method may be infeasible in the presence of discontinuity or noise. Iterative reconstruction methods (e.g. iterative Sparse Asymptotic Minimum Variance[10]) could provide metal artefact reduction, noise and dose reduction for the reconstructed result that attract much research interest around the world.

Inversion formulas

[edit]

Explicit and computationally efficient inversion formulas for the Radon transform and its dual are available. The Radon transform in dimensions can be inverted by the formula:[11] where , and the power of the Laplacian is defined as a pseudo-differential operator if necessary by the Fourier transform: For computational purposes, the power of the Laplacian is commuted with the dual transform to give:[12] where is the Hilbert transform with respect to the s variable. In two dimensions, the operator appears in image processing as a ramp filter.[13] One can prove directly from the Fourier slice theorem and change of variables for integration that for a compactly supported continuous function of two variables: Thus in an image processing context the original image can be recovered from the 'sinogram' data by applying a ramp filter (in the variable) and then back-projecting. As the filtering step can be performed efficiently (for example using digital signal processing techniques) and the back projection step is simply an accumulation of values in the pixels of the image, this results in a highly efficient, and hence widely used, algorithm.

Explicitly, the inversion formula obtained by the latter method is:[4] The dual transform can also be inverted by an analogous formula:

Radon transform in algebraic geometry

[edit]

In algebraic geometry, a Radon transform (also known as the Brylinski–Radon transform) is constructed as follows.

Write

for the universal hyperplane, i.e., H consists of pairs (x, h) where x is a point in d-dimensional projective space and h is a point in the dual projective space (in other words, x is a line through the origin in (d+1)-dimensional affine space, and h is a hyperplane in that space) such that x is contained in h.

Then the Brylinksi–Radon transform is the functor between appropriate derived categories of étale sheaves

The main theorem about this transform is that this transform induces an equivalence of the categories of perverse sheaves on the projective space and its dual projective space, up to constant sheaves.[14]

See also

[edit]

Notes

[edit]
  1. ^ Radon 1917.
  2. ^ Odložilík, Michal (2023-08-31). Detachment tomographic inversion study with fast visible cameras on the COMPASS tokamak (Bachelor's thesis). Czech Technical University in Prague. hdl:10467/111617.
  3. ^ Radon 1986.
  4. ^ a b Roerdink 2001.
  5. ^ Helgason 1984, Lemma I.2.1.
  6. ^ Lax, P. D.; Philips, R. S. (1964). "Scattering theory". Bull. Amer. Math. Soc. 70 (1): 130–142. doi:10.1090/s0002-9904-1964-11051-x.
  7. ^ Bonneel, N.; Rabin, J.; Peyre, G.; Pfister, H. (2015). "Sliced and Radon Wasserstein Barycenters of Measures". Journal of Mathematical Imaging and Vision. 51 (1): 22–25. Bibcode:2015JMIV...51...22B. doi:10.1007/s10851-014-0506-3. S2CID 1907942.
  8. ^ Rim, D. (2018). "Dimensional Splitting of Hyperbolic Partial Differential Equations Using the Radon Transform". SIAM J. Sci. Comput. 40 (6): A4184–A4207. arXiv:1705.03609. Bibcode:2018SJSC...40A4184R. doi:10.1137/17m1135633. S2CID 115193737.
  9. ^ a b c Candès 2016b.
  10. ^ Abeida, Habti; Zhang, Qilin; Li, Jian; Merabtine, Nadjim (2013). "Iterative Sparse Asymptotic Minimum Variance Based Approaches for Array Processing" (PDF). IEEE Transactions on Signal Processing. 61 (4). IEEE: 933–944. arXiv:1802.03070. Bibcode:2013ITSP...61..933A. doi:10.1109/tsp.2012.2231676. ISSN 1053-587X. S2CID 16276001.
  11. ^ Helgason 1984, Theorem I.2.13.
  12. ^ Helgason 1984, Theorem I.2.16.
  13. ^ Nygren 1997.
  14. ^ Kiehl & Weissauer (2001, Ch. IV, Cor. 2.4)
  15. ^ van Ginkel, Hendricks & van Vliet 2004.

References

[edit]

Further reading

[edit]
[edit]