Mitchell order

In mathematical set theory, the Mitchell order is a well-founded preorder on the set of normal measures on a measurable cardinal κ. It is named for . We say that M ◅ N (this is a strict order) if M is in the ultrapower model defined by N. Intuitively, this means that M is a weaker measure than N (note, for example, that κ will still be measurable in the ultrapower for N, since M is a measure on it).

In fact, the Mitchell order can be defined on the set (or proper class, as the case may be) of extenders for κ; but if it is so defined it may fail to be transitive, or even well-founded, provided κ has sufficiently strong large cardinal properties. Well-foundedness fails specifically for rank-into-rank extenders; but Itay Neeman showed in 2004 that it holds for all weaker types of extender.

The Mitchell rank of a measure is the order type of its predecessors under ◅; since ◅ is well-founded this is always an ordinal.

A cardinal that has measures of Mitchell rank α for each α < β is said to be β-measurable.

References[]

• John Steel (Sep 1993). "The Well-Foundedness of the Mitchell Order". Journal of Symbolic Logic. 58 (3): 931–940. doi:10.2307/2275105.
• Itay Neeman (2004). "The Mitchell order below rank-to-rank". Journal of Symbolic Logic. 69 (4): 1143–1162. doi:10.2178/jsl/1102022215.
• Akihiro Kanamori (1997). The Higher Infinite. Perspectives in Mathematical Logic. Springer.
• Donald A. Martin and John Steel (1994). "Iteration trees". Journal of the American Mathematical Society. 7: 1–73. doi:10.2307/2152720.CS1 maint: uses authors parameter (link)
• William Mitchell (1974). "Sets constructible from sequences of ultrafilters". Journal of Symbolic Logic. 39: 57–66. doi:10.2307/2272343.