Riesz transform

In the mathematical theory of harmonic analysis, the Riesz transforms are a family of generalizations of the Hilbert transform to Euclidean spaces of dimension d > 1. They are a type of singular integral operator, meaning that they are given by a convolution of one function with another function having a singularity at the origin. Specifically, the Riesz transforms of a complex-valued function ƒ on R^d are defined by

${\displaystyle R_{j}f(x)=c_{d}\lim _{\epsilon \to 0}\int _{\mathbf {R} ^{d}\backslash B_{\epsilon }(x)}{\frac {(x_{j}-t_{j})f(t)}{|x-t|^{d+1}}}\,dt}$

(1)

for j = 1,2,...,d. The constant c_d is a dimensional normalization given by

${\displaystyle c_{d}={\frac {1}{\pi \omega _{d-1}}}={\frac {\Gamma [(d+1)/2]}{\pi ^{(d+1)/2}}}.}$

where ω_d−1 is the volume of the unit (d − 1)-ball. The limit is written in various ways, often as a principal value, or as a convolution with the tempered distribution

${\displaystyle K(x)={\frac {1}{\pi \omega _{d-1}}}\,p.v.{\frac {x_{j}}{|x|^{d+1}}}.}$

The Riesz transforms arises in the study of differentiability properties of harmonic potentials in potential theory and harmonic analysis. In particular, they arise in the proof of the Calderón-Zygmund inequality (Gilbarg & Trudinger 1983, §9.4).

Multiplier properties

The Riesz transforms are given by a Fourier multiplier. Indeed, the Fourier transform of R_jƒ is given by

${\displaystyle {\mathcal {F}}(R_{j}f)(x)=-i{\frac {x_{j}}{|x|}}({\mathcal {F}}f)(x).}$ 

In this form, the Riesz transforms are seen to be generalizations of the Hilbert transform. The kernel is a distribution which is homogeneous of degree zero. A particular consequence of this last observation is that the Riesz transform defines a bounded linear operator from L²(R^d) to itself.^[1]

This homogeneity property can also be stated more directly without the aid of the Fourier transform. If σ_s is the dilation on R^d by the scalar s, that is σ_sx = sx, then σ_s defines an action on functions via pullback:

${\displaystyle \sigma _{s}^{*}f=f\circ \sigma _{s}.}$ 

The Riesz transforms commute with σ_s:

${\displaystyle \sigma _{s}^{*}(R_{j}f)=R_{j}(\sigma _{x}^{*}f).}$ 

Similarly, the Riesz transforms commute with translations. Let τ_a be the translation on R^d along the vector a; that is, τ_a(x) = x + a. Then

${\displaystyle \tau _{a}^{*}(R_{j}f)=R_{j}(\tau _{a}^{*}f).}$ 

For the final property, it is convenient to regard the Riesz transforms as a single vectorial entity Rƒ = (R₁ƒ,...,R_dƒ). Consider a rotation ρ in R^d. The rotation acts on spatial variables, and thus on functions via pullback. But it also can act on the spatial vector Rƒ. The final transformation property asserts that the Riesz transform is equivariant with respect to these two actions; that is,

${\displaystyle \rho ^{*}R_{j}[(\rho ^{-1})^{*}f]=\sum _{k=1}^{d}\rho _{jk}R_{k}f.}$ 

These three properties in fact characterize the Riesz transform in the following sense. Let T=(T₁,...,T_d) be a d-tuple of bounded linear operators from L²(R^d) to L²(R^d) such that

• T commutes with all dilations and translations.
• T is equivariant with respect to rotations.

Then, for some constant c, T = cR.

Relationship with the Laplacian

Somewhat imprecisely, the Riesz transforms of ${\displaystyle f}$  give the first partial derivatives of a solution of the equation

${\displaystyle {(-\Delta )^{\frac {1}{2}}u=f},}$ 

where Δ is the Laplacian. Thus the Riesz transform of ${\displaystyle f}$  can be written as:

${\displaystyle {Rf=\nabla (-\Delta )^{-{\frac {1}{2}}}f}}$ 

In particular, one should also have

${\displaystyle R_{i}R_{j}\Delta u=-{\frac {\partial ^{2}u}{\partial x_{i}\partial x_{j}}},}$ 

so that the Riesz transforms give a way of recovering information about the entire Hessian of a function from knowledge of only its Laplacian.

This is now made more precise. Suppose that ${\displaystyle u}$  is a Schwartz function. Then indeed by the explicit form of the Fourier multiplier, one has

${\displaystyle R_{i}R_{j}(\Delta u)=-{\frac {\partial ^{2}u}{\partial x_{i}\partial x_{j}}}.}$ 

The identity is not generally true in the sense of distributions. For instance, if ${\displaystyle u}$  is a tempered distribution such that ${\displaystyle \Delta u\in L^{2}(\mathbb {R} ^{d})}$ , then one can only conclude that

${\displaystyle {\frac {\partial ^{2}u}{\partial x_{i}\partial x_{j}}}=-R_{i}R_{j}\Delta u+P_{ij}(x)}$ 

for some polynomial ${\displaystyle P_{ij}}$ .

See also

• Hilbert Transform
• Poisson kernel
• Riesz potential

References

1. Strictly speaking, the definition (1) may only make sense for Schwartz function f. Boundedness on a dense subspace of L² implies that each Riesz transform admits a continuous linear extension to all of L².

• Gilbarg, D.; Trudinger, Neil (1983), Elliptic Partial Differential Equations of Second Order, New York: Springer, ISBN 3-540-41160-7.
• Stein, Elias (1970), Singular integrals and differentiability properties of functions, Princeton University Press.
• Stein, Elias; Weiss, Guido (1971), Introduction to Fourier Analysis on Euclidean Spaces, Princeton University Press, ISBN 0-691-08078-X.
• Arcozzi, N. (1998), Riesz Transform on spheres and compact Lie groups, New York: Springer, doi:10.1007/BF02384766, ISSN 0004-2080, S2CID 119919955.