Jensen's covering theorem

Last updated December 25, 2023

In set theory, Jensen's covering theorem states that if 0^# does not exist then every uncountable set of ordinals is contained in a constructible set of the same cardinality. Informally this conclusion says that the constructible universe is close to the universe of all sets. The first proof appeared in ( Devlin & Jensen 1975 ). Silver later gave a fine-structure-free proof using his machines ^[1] and finally Magidor ( 1990 ) gave an even simpler proof.

The converse of Jensen's covering theorem is also true: if 0^# exists then the countable set of all cardinals less than $\aleph _{\omega }$ cannot be covered by a constructible set of cardinality less than $\aleph _{\omega }$ .

In his book Proper Forcing, Shelah proved a strong form of Jensen's covering lemma.

Hugh Woodin states it as:^[2]

Theorem 3.33 (Jensen). One of the following holds.

(1) Suppose λ is a singular cardinal. Then λ is singular in L and its successor cardinal is its successor cardinal in L.

(2) Every uncountable cardinal is inaccessible in L.

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References

Devlin, Keith I.; Jensen, R. Björn (1975), "Marginalia to a theorem of Silver", ISILC Logic Conference (Proc. Internat. Summer Inst. and Logic Colloq., Kiel, 1974), Lecture Notes in Mathematics, vol. 499, Berlin, New York: Springer-Verlag, pp. 115–142, doi:10.1007/BFb0079419, ISBN 978-3-540-07534-9, MR 0480036
Magidor, Menachem (1990), "Representing sets of ordinals as countable unions of sets in the core model", Transactions of the American Mathematical Society , 317 (1): 91–126, doi: 10.2307/2001455 , ISSN 0002-9947, JSTOR 2001455, MR 0939805
Mitchell, William (2010), "The covering lemma", Handbook of Set Theory, Springer, pp. 1497–1594, doi:10.1007/978-1-4020-5764-9_19, ISBN 978-1-4020-4843-2
Shelah, Saharon (1982), Proper forcing, Lecture Notes in Mathematics, vol. 940, Berlin, New York: Springer-Verlag, doi:10.1007/BFb0096536, hdl: 10338.dmlcz/143570 , ISBN 978-3-540-11593-9, MR 0675955

Notes

↑ W. Mitchell, Inner models for large cardinals (2012, p.16). Accessed 2022-12-08.
↑ "In search of Ultimate-L" Version: January 30, 2017

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[1] W. Mitchell, Inner models for large cardinals (2012, p.16). Accessed 2022-12-08.

[2] "In search of Ultimate-L" Version: January 30, 2017

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