Difference between revisions of "Elliott-Daboussi theorem"

The Delange theorem, proved in 1961, gives necessary and sufficient conditions for a multiplicative arithmetic function $ f : \mathbf N \rightarrow \mathbf C $, of modulus $ | f | \leq 1 $, to possess a non-zero mean value. The unpleasant condition $ | f | \leq 1 $ was replaced by P.D.T.A. Elliott, in 1975–1980, by boundedness of a semi-norm

$$ \left \| f \right \| _ {q} = \left ( \limsup _ {x \rightarrow \infty }{ \frac{1}{x} } \cdot \sum _ {n \leq x } \left | {f ( n ) } \right | ^ {q} \right ) ^ { {1 / q } } . $$

More precisely, Elliott showed (see [a4], [a6]) the following result. Assume that $ q > 1 $ and that $ f $ is a multiplicative arithmetic function with bounded semi-norm $ \| f \| _ {q} $. Then the mean value

$$ M ( f ) = {\lim\limits } _ {x \rightarrow \infty } { \frac{1}{x} } \cdot \sum _ {n \leq x } f ( n ) $$

of $ f $ exists and is non-zero if and only if

i) the four series

$$ S _ {1} ( f ) = \sum _ { p } { \frac{1}{p} } \cdot ( f ( p ) - 1 ) , $$

$$ S _ {2} ^ \prime ( f ) = \sum _ {\left \{ p : {\left | {f ( p ) } \right | \leq {5 / 4 } } \right \} } { \frac{1}{p} } \cdot \left | {f ( p ) - 1 } \right | ^ {2} , $$

$$ S _ {2,q } ^ {\prime \prime } ( f ) = \sum _ {\left \{ p : {\left | {f ( p ) } \right | > {5 / 4 } } \right \} } { \frac{1}{p} } \cdot \left | {f ( p ) } \right | ^ {q} , $$

$$ S _ {3,q } ( f ) = \sum _ { p } \sum _ {k \geq 2 } { \frac{1}{p ^ {k} } } \cdot \left | {f ( p ^ {k} ) } \right | ^ {q} $$

are convergent; and

ii) $ \sum _ {k = 0 } ^ \infty p ^ {- k } \cdot f ( p ^ {k} ) \neq 0 $ for every prime $ p $.

H. Daboussi [a3] gave another proof for this result and extended it [a2] to multiplicative functions $ f $ having at least one non-zero Fourier coefficient $ {\widehat{f} } ( \alpha ) = M ( n \mapsto f ( n ) \cdot { \mathop{\rm exp} } \{ 2 \pi i \cdot \alpha n \} ) $; the necessary and sufficient conditions for this to happen are the convergence of the series $ S _ {1} ( \chi f ) $, $ S _ {2} ^ \prime ( \chi f ) $, $ S _ {2,q } ^ {\prime \prime } ( f ) $, and $ S _ {3,q } ( f ) $ for some Dirichlet character $ \chi $.

See also [a5], [a7], [a8], [a9], [a1]. In fact, the conditions of the Elliott–Daboussi theorem ensure that $ f $ belongs to the space $ {\mathcal B} ^ {q} $, which is the $ \| \cdot \| _ {q} $- closure of the vector space of linear combinations of the Ramanujan sums $ c _ {r} $, $ r = 1,2, \dots $. For details see [a10], Chapts. VI, VII.

References