Pinsky phenomenon

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Short description: Non-convergence in Fourier analysis


In mathematics, the Pinsky phenomenon is a result in Fourier analysis.[1] This phenomenon was discovered by Mark Pinsky of Northwestern University. It involves the spherical inversion of the Fourier transform. The phenomenon involves a lack of convergence at a point due to a discontinuity at boundary. This lack of convergence in the Pinsky phenomenon happens far away from the boundary of the discontinuity, rather than at the discontinuity itself seen in the Gibbs phenomenon. This non-local phenomenon is caused by a lensing effect.

Prototypical example

Let a function g(x) = 1 for |x| < c in 3 dimensions, with g(x) = 0 elsewhere. The jump at |x| = c will cause an oscillatory behavior of the spherical partial sums, which prevents convergence at the center of the ball as well as the possibility of Fourier inversion at x = 0. Stated differently, spherical partial sums of a Fourier integral of the indicator function of a ball are divergent at the center of the ball but convergent elsewhere to the desired indicator function. This prototype example was coined the ”Pinsky phenomenon” by Jean-Pierre Kahane, CRAS, 1995.

Generalizations

This prototype example can be suitably generalized to Fourier integral expansions in higher dimensions, both in Euclidean space and other non-compact rank-one symmetric spaces. Also related are eigenfunction expansions on a geodesic ball in a rank-one symmetric space, but one must consider boundary conditions. Pinsky and others also represent some results on the asymptotic behavior of the Fejer approximation in one dimension, inspired by work of Bump, Persi Diaconis, and J. B. Keller.

References

  1. Taylor (2002). "The Gibbs phenomenon, the Pinsky phenomenon, and variants for eigenfunction expansions". Communications in Partial Differential Equations 27 (3): 565–605. doi:10.1081/PDE-120002866. 
  • Mathematics that describe the Pinsky phenomenon are available on pages 142 to 143, and generalizations on pages 143+, in the book Introduction to Fourier Analysis and Wavelets, by Mark A. Pinsky, 2002, ISBN 978-0-534-37660-4 Publisher: Thomson Brooks/Cole.