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| Format: | Preprint |
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2024
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| Online Access: | https://arxiv.org/abs/2401.06871 |
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| _version_ | 1866911609109086208 |
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| author | Hedenmalm, H. Montes-Rodriguez, A. |
| author_facet | Hedenmalm, H. Montes-Rodriguez, A. |
| contents | In an effort to extend classical Fourier theory, Hedenmalm and Montes-Rodr\'ıguez (2011) found that the function system \[ e_m(x)=e^{iπmx},\quad e_n^\dagger(x)=e_n(-1/x)=e^{-iπn/x} \] is weak-star complete in $L^{\infty}(\mathbb{R})$ when $m,n$ range over the integers with $n\ne0$. It turns out that the system can be used to provide unique representation of functions and more generally distributions on the real line $\mathbb{R}$. For instance, we may represent uniquely the unit point mass at a point $x\in\mathbb{R}$: \[ δ_x(t)=A_0(x)+\sum_{n\ne0}\big(A_n(x)\,e^{iπnt} +B_n(x)\,e^{-iπn/t}\big), \] with at most polynomial growth of the coefficients, so that the sum converges in the sense of distribution theory. In a natural sense, the system $\{A_n,B_n\}_n$ is biorthogonal to the initial system $\{e_n,e_n^\dagger\}_n$ on the real line. More generally, for a distribution $f$ on the compactified real line, we may decompose it in a \emph{hyperbolic Fourier series} \[ f(t)=a_0(f)+\sum_{n\ne0}\big(a_n(f)\,e^{iπnt}+b_n(f)\,e^{-iπn/t}\big), \] understood to converge in the sense of distribution theory. Such hyperbolic Fourier series arise from two different considerations. One is the Fourier interpolation problem of recovering a radial function $ϕ$ on $\mathbb{R}^d$ from partial information on $ϕ$ and its Fourier transform $\hat ϕ$, studied by Radchenko and Viazovska (2019). Another consideration is the interpolation theory of the Klein-Gordon equation $\partial_x\partial_y u+u=0$. For instance, the biorthogonal system $\{A_n,B_n\}_n$ leads to a collection of solutions that vanish along the lattice-cross of points $(πk,0)$ and $(0,πl)$ save for one of these points. These interpolating solutions allow for restoration of a given solution $u$ from its values on the lattice-cross. |
| format | Preprint |
| id |
arxiv_https___arxiv_org_abs_2401_06871 |
| institution | arXiv |
| publishDate | 2024 |
| record_format | arxiv |
| spellingShingle | Hyperbolic Fourier series and the Klein-Gordon equation Hedenmalm, H. Montes-Rodriguez, A. Analysis of PDEs Complex Variables Dynamical Systems 81Q05, 42A10, 30B50 In an effort to extend classical Fourier theory, Hedenmalm and Montes-Rodr\'ıguez (2011) found that the function system \[ e_m(x)=e^{iπmx},\quad e_n^\dagger(x)=e_n(-1/x)=e^{-iπn/x} \] is weak-star complete in $L^{\infty}(\mathbb{R})$ when $m,n$ range over the integers with $n\ne0$. It turns out that the system can be used to provide unique representation of functions and more generally distributions on the real line $\mathbb{R}$. For instance, we may represent uniquely the unit point mass at a point $x\in\mathbb{R}$: \[ δ_x(t)=A_0(x)+\sum_{n\ne0}\big(A_n(x)\,e^{iπnt} +B_n(x)\,e^{-iπn/t}\big), \] with at most polynomial growth of the coefficients, so that the sum converges in the sense of distribution theory. In a natural sense, the system $\{A_n,B_n\}_n$ is biorthogonal to the initial system $\{e_n,e_n^\dagger\}_n$ on the real line. More generally, for a distribution $f$ on the compactified real line, we may decompose it in a \emph{hyperbolic Fourier series} \[ f(t)=a_0(f)+\sum_{n\ne0}\big(a_n(f)\,e^{iπnt}+b_n(f)\,e^{-iπn/t}\big), \] understood to converge in the sense of distribution theory. Such hyperbolic Fourier series arise from two different considerations. One is the Fourier interpolation problem of recovering a radial function $ϕ$ on $\mathbb{R}^d$ from partial information on $ϕ$ and its Fourier transform $\hat ϕ$, studied by Radchenko and Viazovska (2019). Another consideration is the interpolation theory of the Klein-Gordon equation $\partial_x\partial_y u+u=0$. For instance, the biorthogonal system $\{A_n,B_n\}_n$ leads to a collection of solutions that vanish along the lattice-cross of points $(πk,0)$ and $(0,πl)$ save for one of these points. These interpolating solutions allow for restoration of a given solution $u$ from its values on the lattice-cross. |
| title | Hyperbolic Fourier series and the Klein-Gordon equation |
| topic | Analysis of PDEs Complex Variables Dynamical Systems 81Q05, 42A10, 30B50 |
| url | https://arxiv.org/abs/2401.06871 |