Local Bernstein theory, and lower bounds for Lebesgue constants
Abstract
Classical (or ``global'') Bernstein theory establishes sharp control on entire functions of exponential type that are bounded and real-valued on the real axis. We localize some of this theory to rectangular regions \ x+iy: x ∈ I, 0 ≤ y ≤ y0 \, showing that Bernstein-type bounds with acceptable errors can continue to hold for functions holomorphic in such rectangles, bounded and real-valued on the lower edge of the rectangle, at most exponentially large on the upper edge, and at most double exponentially large on the vertical sides. As a consequence of these bounds, we are able to localize the Erdos lower bound x ∈ [-1,1] λ(x) ≥ 2π n - O(1) on the Lebesgue constant of interpolation on C([-1,1]) to shorter intervals I than [-1,1], answering a question of Erdos and Tur\'an. By using suitably weighted versions of the residue theorem, we also obtain the asymptotically sharp lower bound ∫I λ(x)\ dx ≥ 4|I|π2 n - o( n) for integral variants of such constants, answering a further question of Erdos.
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