Taylor coefficients and zeroes of entire functions of exponential type

Abstract

Let F be an entire function of exponential type represented by the Taylor series \[ F(z) = Σn 0 ωn znn! \] with unimodular coefficients |ωn|=1. We show that either the counting function nF(r) of zeroes of F grows linearly at infinity, or F is an exponential function. The same conclusion holds if only a positive asymptotic proportion of the coefficients ωn is unimodular. This significantly extends a classical result of Carlson (1915). The second result requires less from the coefficient sequence ω, but more from the counting function of zeroes nF. Assuming that 0<c |ωn| C <∞, n∈ Z+, we show that nF(r) = o(r) as r∞, implies that F is an exponential function. The same conclusion holds if, for some α<1/2, nF(rj)=O(rjα) only along a sequence rj∞. Furthermore, this conclusion ceases to hold if nF(r)=O( r) as r∞.

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