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Automorphisms of supermaximal subspaces

Published online by Cambridge University Press:  12 March 2014

R. G. Downey  and
G. R. Hird
R. G. Downey
Affiliation:
Department of Mathematics, National University of Singapore, Kent Ridge, 0511, Singapore
G. R. Hird
Affiliation:
Department of Mathematics, Monash University, Clayton, Victoria 3168, Australia
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Extract

An infinite-dimensional vector space V over a recursive field F is called fully effective if V is a recursive set identified with ω upon which the operations of vector addition and scalar multiplication are recursive functions, identity is a recursive relation, and V has a dependence algorithm, that is a uniformly effective procedure which when applied to x, a1,…,an, ∈ V determines whether or not x is an element of {a1,…,an}* (the subspace generated by {a1,…,an}). The study of V, and of its lattice of r.e. subspaces L(V), was introduced in Metakides and Nerode [15]. Since then both V and L(V) (and many other effective algebraic systems) have been studied quite intensively. The reader is directed to [5] and [17] for a good bibliography in this area, and to [15] for any unexplained notation and terminology.

In [15] Metakides and Nerode observed that a study of L(V) may in some ways be modelled upon a study of L(ω), the lattice of r.e. sets. For example, they showed how an e-state construction could be modified to produce an r.e. maximal subspace, where ML(V) is maximal if dim(V/M) = ∞ and, for all WL(V), if WM then either dim(W/M) < ∞ or dim(V/W) < ∞.

However, some of the most interesting features of L(V) are those which do not have analogues in L(ω). Our concern here, which is probably one of the most striking characteristics of L(V), falls into this category. We say ML(V) is supermaximal if dim(V/M) = ∞ and for all WL(V), if WM then dim(W/M) < ∞ or W = V. These subspaces were discovered by Kalantari and Retzlaff [13].

Type
Research Article
Information
The Journal of Symbolic Logic , Volume 50 , Issue 1 , March 1985 , pp. 1 - 9
Copyright
Copyright © Association for Symbolic Logic 1985

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References

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