Square principle

In mathematical set theory, a square principle is a combinatorial principle asserting the existence of a cohering sequence of short closed unbounded (club) sets so that no one (long) club set coheres with them all. As such they may be viewed as a kind of incompactness phenomenon.^[1] They were introduced by Ronald Jensen in his analysis of the fine structure of the constructible universe L.

Definition[edit]

Define Sing to be the class of all limit ordinals which are not regular. Global square states that there is a system $(C_{\beta })_{\beta \in \mathrm {Sing} }$ satisfying:

$C_{\beta }$ is a club set of $\beta$ .
ot $(C_{\beta })<\beta$
If $\gamma$ is a limit point of $C_{\beta }$ then $\gamma \in \mathrm {Sing}$ and $C_{\gamma }=C_{\beta }\cap \gamma$

Variant relative to a cardinal[edit]

Jensen introduced also a local version of the principle.^[2] If $\kappa$ is an uncountable cardinal, then $\Box _{\kappa }$ asserts that there is a sequence $(C_{\beta }\mid \beta {\text{ a limit point of }}\kappa ^{+})$ satisfying:

$C_{\beta }$ is a club set of $\beta$ .
If $cf\beta <\kappa$ , then $|C_{\beta }|<\kappa$
If $\gamma$ is a limit point of $C_{\beta }$ then $C_{\gamma }=C_{\beta }\cap \gamma$

Jensen proved that this principle holds in the constructible universe for any uncountable cardinal κ.

Notes[edit]

^ Cummings, James (2005), "Notes on Singular Cardinal Combinatorics", Notre Dame Journal of Formal Logic, 46 (3): 251–282, doi:10.1305/ndjfl/1125409326 Section 4.
^ Jech, Thomas (2003), Set Theory: Third Millennium Edition, Springer Monographs in Mathematics, Berlin, New York: Springer-Verlag, ISBN 978-3-540-44085-7, p. 443.

Jensen, R. Björn (1972), "The fine structure of the constructible hierarchy", Annals of Mathematical Logic, 4 (3): 229–308, doi:10.1016/0003-4843(72)90001-0, MR 0309729

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[1] Cummings, James (2005), "Notes on Singular Cardinal Combinatorics", Notre Dame Journal of Formal Logic, 46 (3): 251–282, doi:10.1305/ndjfl/1125409326 Section 4.

[2] Jech, Thomas (2003), Set Theory: Third Millennium Edition, Springer Monographs in Mathematics, Berlin, New York: Springer-Verlag, ISBN 978-3-540-44085-7, p. 443.

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