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Co-immune subspaces and complementation in V

Published online by Cambridge University Press:  12 March 2014

R. Downey*
Affiliation:
Monash University, Clayton, Victoria 3168, Australia Chisholm Institute of Technology, 900 Dandenong Road, Caulfield East, Victoria 3145, Australia
*
National University of Singapore, Kent Ridge, 0511, Singapore

Abstract

We examine the multiplicity of complementation amongst subspaces of V. A subspace V is a complement of a subspace W if VW = {0} and (VW)* = V. A subspace is called fully co-r.e. if it is generated by a co-r.e. subset of a recursive basis of V. We observe that every r.e. subspace has a fully co-r.e. complement.

Theorem. If S is any fully co-r.e. subspace then S has a decidable complement.

We give an analysis of other types of complements S may have. For example, if S is fully co-r.e. and nonrecursive, then S has a (nonrecursive) r.e. nowhere simple complement.

We impose the condition of immunity upon our subspaces.

Theorem. Suppose V is fully co-r.e. Then V is immune iff there exist M1, M2L(V), with M1supermaximal and M2k-thin, such that M1, ⊕ V = M2V = V.

Corollary. Suppose V is any r.e. subspace with a fully co-r.e. immune complement W(e.g., V is maximal or V is h-immune). Then there exist an r.e. supermaximal subspace M and a decidable subspace D such that VW = MW = DW = V.

We indicate how one may obtain many further results of this type. Finally we examine a generalization of the concepts of immunity and soundness. A subspace V of V is nowhere sound if (i) for all Q ∈ L(V) if QV then Q = V, (ii) V is immune and (iii) every complement of V is immune. We analyse the existence (and ramifications of the existence) of nowhere sound spaces.

Type
Research Article
Copyright
Copyright © Association for Symbolic Logic 1984

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