Lindelöf theorem

on asymptotic values

1) Let $ w = f ( z) $ be a bounded regular analytic function in the unit disc $ D = \{ {z } : {| z | < 1 } \} $ and let $ \alpha $ be the asymptotic value of $ f ( z) $ along a Jordan arc $ L $ situated in $ D $ and ending at a point $ e ^ {i \theta _ {0} } $, that is, $ f ( z) \rightarrow \alpha $ as $ z \rightarrow e ^ {i \theta _ {0} } $ along $ L $. Then $ \alpha $ is the angular boundary value (non-tangential boundary value) of $ f ( z) $ at $ e ^ {i \theta _ {0} } $, that is, $ f ( z) $ tends uniformly to $ \alpha $ as $ z \rightarrow e ^ {i \theta _ {0} } $ inside an angle with vertex $ e ^ {i \theta _ {0} } $ formed by two chords of the disc $ D $.

The Lindelöf theorem is also true in domains $ D $ of other types, and the conditions on $ f ( z) $ have been significantly weakened. For example, it is sufficient to require that $ f ( z) $ is a meromorphic function in $ D $ that does not assume three different values. Lindelöf's theorem can also be generalized to functions $ f ( z) $ of several complex variables $ z = ( z _ {1} \dots z _ {n} ) $. For example, if $ f ( z) $ is a bounded holomorphic function in the ball $ D = \{ {z } : {| z | < 1 } \} $ that has asymptotic value $ \alpha $ along a non-tangential path $ L $ at a point $ \zeta \in \partial D $, then $ \alpha $ is the non-tangential boundary value of $ f ( z) $ at $ \zeta $( see [4]).

2) Let $ w = f ( z) $ be a bounded regular analytic function in the disc $ D = \{ {z } : {| z | < 1 } \} $ that has asymptotic values $ \alpha $ and $ \beta $ along two distinct paths $ L _ {1} $ and $ L _ {2} $ that end at the point $ e ^ {i \theta _ {0} } $. Then $ \alpha = \beta $ and $ f ( z) \rightarrow \alpha $ uniformly inside the angle between the paths $ L _ {1} $ and $ L _ {2} $. This theorem is also true for domains $ D $ of other types. For unbounded functions it is false, generally speaking.

These theorems were discovered by E. Lindelöf [1].

References

Comments

For the generalization of Lindelöf's theorem to functions of several variables, the condition that the path $ L $ is non-tangential may be weakened, see [a1], Chapt. 8.

References

[a1]	W. Rudin, "Function theory in the unit ball in " , Springer (1980)