Definition:Universe (Set Theory)

Definition
Sets are considered to be subsets of some large universal set, also called the universe.

Exactly what this universe is will vary depending on the subject and context.

When discussing particular sets, it should be made clear just what that universe is.

However, note that from There Exists No Universal Set, this universe cannot be everything that there is.

The traditional symbol used to signify the universe is $\mathfrak A$.

However, this is old-fashioned and inconvenient, so some newer texts have taken to using $\mathbb U$ or just $U$ instead.

With this notation, this definition can be put into symbols as:
 * $\forall S: S \subseteq \mathbb U$

The use of $\mathbb U$ or a variant is not universal: some sources use $X$.

Zermelo-Fraenkel Theory
If the universal class is allowed to be a set in ZF(C) set theory, then a contradiction results. One equivalent of the Axiom of Subsets states that:


 * $\forall z: \forall A: \paren {A \subseteq z \implies A \in U}$

However, we may conservatively extend the ZFC axioms to incorporate classes, which is done in von Neumann–Bernays–Gödel (NBG) set theory.

The basic gadget we work with is a class, and a set is defined to be an element of a class. Some refer to a proper class to be one which is not contained in any class (so an "improper" class would be one that is contained in some class, thus it is a set).

We avoid the contradiction mentioned by modifying the Axiom of Subsets through restricting quantifiers to range over sets, but not all classes. (We also demand that sets are not bijective to the class of all ordinals.)

Michael Shulman's "Set theory for category theory" (arXiv:0810.1279v2 [math.CT]) studies various esoteric foundational issues relevant for category theory, and gives the definition of a Universe in any set theory as: a model for the ZFC axioms. This covers the von Neumann universe, the Grothendieck universe, the class of all sets in NBG set theory, etc.

However, some alternative set theories, such as Quine's New Foundations, allow the universal set to be a value of a variable, and reject certain instances of the Axiom of Subsets.

All the elements of the universal set are precisely the Universe of Discourse of quantification.

Also known as
Some sources refer to the universal set as the universe of discourse, which name is also used for a similar concept in the category of predicate logic.

Some sources (particularly in the context of probability theory) refer to it as the space.

Also see

 * Definition:Universe of Discourse
 * Definition:Universal Class
 * Definition:Population


 * There Exists No Universal Set