Solovay model

In the mathematical field of set theory, the Solovay model is a model constructed by Robert M. Solovay (1970) in which all of the axioms of Zermelo–Fraenkel set theory (ZF) hold, exclusive of the axiom of choice, but in which all sets of real numbers are Lebesgue measurable. The construction relies on the existence of an inaccessible cardinal.

In this way Solovay showed that the axiom of choice is essential to the proof of the existence of a non-measurable set, at least granted that the existence of an inaccessible cardinal is consistent with ZFC, the axioms of Zermelo–Fraenkel set theory including the axiom of choice.

Statement

ZF stands for Zermelo–Fraenkel set theory, and DC for the axiom of dependent choice.

Solovay's theorem is as follows. Assuming the existence of an inaccessible cardinal, there is an inner model of ZF + DC of a suitable forcing extension V[G] such that every set of reals is Lebesgue measurable, has the perfect set property, and has the Baire property.

Construction

Solovay constructed his model in two steps, starting with a model M of ZFC containing an inaccessible cardinal κ.

The first step is to take a Levy collapse M[G] of M by adding a generic set G for the notion of forcing that collapses all cardinals less than κ to ω. Then M[G] is a model of ZFC with the property that every set of reals that is definable over a countable sequence of ordinals is Lebesgue measurable, and has the Baire and perfect set properties. (This includes all definable and projective sets of reals; however for reasons related to Tarski's undefinability theorem the notion of a definable set of reals cannot be defined in the language of set theory, while the notion of a set of reals definable over a countable sequence of ordinals can be.)

The second step is to construct Solovay's model N as the class of all sets in M[G] that are hereditarily definable over a countable sequence of ordinals. The model N is an inner model of M[G] satisfying ZF + DC such that every set of reals is Lebesgue measurable, has the perfect set property, and has the Baire property. The proof of this uses the fact that every real in M[G] is definable over a countable sequence of ordinals, and hence N and M[G] have the same reals.

Instead of using Solovay's model N, one can also use the smaller inner model L(R) of M[G], consisting of the constructible closure of the real numbers, which has similar properties.

Complements

Solovay suggested in his paper that the use of an inaccessible cardinal might not be necessary. Several authors proved weaker versions of Solovay's result without assuming the existence of an inaccessible cardinal. In particular Krivine (1969) showed there was a model of ZFC in which every ordinal-definable set of reals is measurable, Solovay showed there is a model of ZF + DC in which there is some translation-invariant extension of Lebesgue measure to all subsets of the reals. Shelah (1984) showed that there is a model in which all sets of reals have the Baire property (so that the inaccessible cardinal is indeed unnecessary in this case).

The case of the perfect set property was solved by Specker (1957), who showed (in ZF) that if every set of reals has the perfect set property and the first uncountable cardinal ℵ₁ is regular then ℵ₁ is inaccessible in the constructible universe. Combined with Solovay's result, this shows that the statements "There is an inaccessible cardinal" and "Every set of reals has the perfect set property" are equiconsistent over ZF.

Finally Shelah (1984) showed that consistency of an inaccessible cardinal is also necessary for constructing a model in which all sets of reals are Lebesgue measurable. More precisely he showed that if every Σ1
3 set of reals is measurable then the first uncountable cardinal ℵ₁ is inaccessible in the constructible universe, so that the condition about an inaccessible cardinal cannot be dropped from Solovay's theorem. Shelah also showed that the Σ1
3 condition is close to best possible, by constructing a model (without using an inaccessible cardinal) in which all Δ1
3 sets of reals are measurable. See Raisonnier (1984) and Stern (1985) and Miller (1989) for expositions of Shelah's result.

Shelah & Woodin (1990) showed that if supercompact cardinals exist then every set of reals in L(R) (the constructible sets generated by the reals) is Lebesgue measurable and has the Baire property; this includes every "reasonably definable" set of reals.

References

• Krivine, Jean-Louis (1969), "Modèles de ZF + AC dans lesquels tout ensemble de réels définissable en termes d'ordinaux est mesurable-Lebesgue", Comptes Rendus Hebdomadaires des Séances de l'Académie des Sciences. Séries A et B, 269: A549––A552, ISSN 0151-0509, MR 0253894 
• Krivine, Jean-Louis (1971), "Théorèmes de consistance en théorie de la mesure de R. Solovay", Séminaire Bourbaki vol. 1968/69 Exposés 347-363, Lecture Notes in Mathematics, 179, pp. 187–197, doi:10.1007/BFb0058812, ISBN 978-3-540-05356-9 
• Miller, Arnold W. (1989), "Review of "Can You Take Solovay's Inaccessible Away? by Saharon Shelah"", The Journal of Symbolic Logic, Association for Symbolic Logic, 54 (2): 633–635, doi:10.2307/2274892, ISSN 0022-4812 
• Raisonnier, Jean (1984), "A mathematical proof of S. Shelah's theorem on the measure problem and related results.", Israel J. Math., 48: 48–56, doi:10.1007/BF02760523, MR 0768265 
• Shelah, Saharon (1984), "Can you take Solovay's inaccessible away?", Israel Journal of Mathematics, 48 (1): 1–47, doi:10.1007/BF02760522, ISSN 0021-2172, MR 768264 
• Shelah, Saharon; Woodin, Hugh (1990), "Large cardinals imply that every reasonably definable set of reals is Lebesgue measurable", Israel Journal of Mathematics, 70 (3): 381–394, doi:10.1007/BF02801471, ISSN 0021-2172, MR 1074499 
• Solovay, Robert M. (1970), "A model of set-theory in which every set of reals is Lebesgue measurable", Annals of Mathematics. Second Series, 92: 1–56, ISSN 0003-486X, JSTOR 1970696, MR 0265151 
• Specker, Ernst (1957), "Zur Axiomatik der Mengenlehre (Fundierungs- und Auswahlaxiom)", Zeitschrift für Mathematische Logik und Grundlagen der Mathematik, 3: 173–210, doi:10.1002/malq.19570031302, ISSN 0044-3050, MR 0099297 
• Stern, Jacques (1985), "Le problème de la mesure", Astérisque (121): 325–346, ISSN 0303-1179, MR 768968