Approximation of Fractals via Lagrange-type Superoscillations
Abstract
We study the approximation of the Weierstrass function by means of superoscillating sequences. Superoscillatory functions are band-limited functions whose local oscillation rate can exceed the highest frequency contained in their Fourier spectrum. Starting from Lagrange-type interpolation at nodes in [-1,1], we construct a double-indexed family WN,n(x) that approximates the truncated Weierstrass function WN(x) for each fixed truncation order~N. We prove that if the number of interpolation nodes nN grows sufficiently fast relative to the highest frequency bNπ, namely bNπ/nN 0, then WN,nN converges uniformly to the full Weierstrass function on every compact set. We also show that the two limits in N and n do not commute: for any fixed~n the series N∞WN,n(x) diverges for every x≠ 0, a phenomenon called the Divergence Wall.
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