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引用次数: 3
摘要
设K是n≥2次的全实数域。K的倒数在Rn中产生了一个晶格。我们证明了在该晶格的“分量平方根”上消失的Rn上的Schwartz-Fourier本征函数的空间是有限维的。由此获得的傅立叶非唯一性集是所有球面并集的离散子集√mS n−1,对于整数m≥0和,作为m→ ∞ , 对于某个显式常数c K,在第m个球面上有~c K m n−1个多点,与K的判别式的平方根成比例。这与Stoller[17,Cor.1-1]最近的傅立叶唯一性结果形成了对比。使用涉及K的协差的不同构造,我们证明了椭球离散子集的相似性。在特殊情况下,这些集合也位于半径更密集的球体上,但每个球体上的点更少。我们还研究了一般格∧⊂Rn的节点为“√∧”的傅立叶插值公式的存在性的一个相关问题。利用关于高阶李群中格的结果,我们证明了如果n≥2,并且某个群Γ∧≤PSL2(R)n是离散的,那么这样的插值公式不可能存在。出于这些更一般的考虑,我们重新审视了一个径向变量的情况,并证明了对于所有n≥5和所有实数λ>2,球面序列(cid:112)2 m/λS n−1的傅立叶插值结果,其中m的范围在任何固定的非负整数集上。该证明依赖于有限体积Hecke群的一系列Poincar´e型,与[17,§4]中的证明类似。
Fourier non-uniqueness sets from totally real number fields
. Let K be a totally real number field of degree n ≥ 2. The inverse different of K gives rise to a lattice in R n . We prove that the space of Schwartz Fourier eigenfunctions on R n which vanish on the “component-wise square root” of this lattice, is infinite dimensional. The Fourier non-uniqueness set thus obtained is a discrete subset of the union of all spheres √ mS n − 1 for integers m ≥ 0 and, as m → ∞ , there are ∼ c K m n − 1 many points on the m -th sphere for some explicit constant c K , proportional to the square root of the discriminant of K . This contrasts a recent Fourier uniqueness result by Stoller [17, Cor. 1.1]. Using a different construction involving the codifferent of K , we prove an analogue for discrete subsets of ellipsoids. In special cases, these sets also lie on spheres with more densely spaced radii, but with fewer points on each. We also study a related question about existence of Fourier interpolation formulas with nodes “ √ Λ” for general lattices Λ ⊂ R n . Using results about lattices in Lie groups of higher rank we prove that if n ≥ 2 and a certain group Γ Λ ≤ PSL 2 ( R ) n is discrete, then such interpolation formulas cannot exist. Motivated by these more general considerations, we revisit the case of one radial variable and prove, for all n ≥ 5 and all real λ > 2, Fourier interpolation results for sequences of spheres (cid:112) 2 m/λS n − 1 , where m ranges over any fixed cofinite set of non-negative integers. The proof relies on a series of Poincar´e type for Hecke groups of infinite covolume and is similar to the one in [17, § 4].
期刊介绍:
Commentarii Mathematici Helvetici (CMH) was established on the occasion of a meeting of the Swiss Mathematical Society in May 1928. The first volume was published in 1929. The journal soon gained international reputation and is one of the world''s leading mathematical periodicals.
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