Abstract
Abstract
We explore the complexity of Sacks’ Splitting Theorem in terms of the mind change functions associated with the members of the splits. We prove that, for any c.e. set A, there are low computably enumerable sets
$A_0\sqcup A_1=A$
splitting A with
$A_0$
and
$A_1$
both totally
$\omega ^2$
-c.a. in terms of the Downey–Greenberg hierarchy, and this result cannot be improved to totally
$\omega $
-c.a. as shown in [9]. We also show that if cone avoidance is added then there is no level below
$\varepsilon _0$
which can be used to characterize the complexity of
$A_1$
and
$A_2$
.
Publisher
Cambridge University Press (CUP)