Riesz interpolation formula

A formula giving an expression for the derivative of a trigonometric polynomial at some point by the values of the polynomial itself at a finite number of points. If $ T _ {n} ( x) $ is a trigonometric polynomial of degree $ n $ with real coefficients, then for any real $ x $ the following equality holds:

$$ T _ {n} ^ \prime ( x) = \frac{1}{4n}

\sum _ { k=1 } ^ { 2n }  (- 1)  ^ {k+1} 

\frac{1}{\sin ^ {2} x _ {k} ^ {( n)} /2 }

T _ {n} ( x + x _ {k}  ^ {( n)} ),

$$

where $ x _ {k} ^ {( n)} = ( 2k- 1) \pi /2n $, $ k = 1, \ldots, 2n $.

Riesz' interpolation formula can be generalized to entire functions of exponential type: If $ f $ is an entire function that is bounded on the real axis $ \mathbf R $ and of order $ \sigma $, then

$$ f ^ { \prime } ( x) = \frac \sigma {\pi ^ {2} }

\sum _ {k = - \infty } ^  \infty   

\frac{(- 1) ^ {k} }{\left ( k+ \frac{1}{2}

\right )  ^ {2} }
f \left ( x + 2k+ 

\frac{1}{2 \sigma }

\pi \right ) ,

\ x \in \mathbf R . $$

Moreover, the series at right-hand side of the equality converges uniformly on the entire real axis.

This result was established by M. Riesz [1].

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