Tree (set theory)

File:Finite set-theoretic trees.png

A tree is a partially ordered set (poset) such that for each $t\backslash in\; T$, the set height, rank, or level{{cite book |last=Monk |first=J. Donald |title=Mathematical Logic |publisher=Springer-Verlag |location=New York |year=1976 |page=[https://archive.org/details/mathematicallogi00jdon/page/517 517] |isbn=0-387-90170-1 |url-access=registration |url=https://archive.org/details/mathematicallogi00jdon/page/517 }} of $t$. The height of $T$ itself is the least ordinal greater than the height of each element of $T$. A root of a tree $T$ is an element of height 0. Frequently trees are assumed to have only one root.

Trees with a single root may be viewed as rooted trees in the sense of graph theory in one of two ways: either as a tree (graph theory) or as a trivially perfect graph. In the first case, the graph is the undirected Hasse diagram of the partially ordered set, and in the second case, the graph is simply the underlying (undirected) graph of the partially ordered set. However, if $T$ is a tree whose height is greater than the smallest infinite ordinal number $\backslash omega$, then the Hasse diagram definition does not work. For example, the partially ordered set $\backslash omega\; +\; 1\; =\; \backslash left\backslash \{0,\; 1,\; 2,\; \backslash dots,\; \backslash omega\backslash right\backslash \}$ does not have a Hasse Diagram, as there is no predecessor to $\backslash omega$. Hence a height of at most $\backslash omega$ is required to define a graph-theoretic tree in this way.

A branch of a tree is a maximal chain in the tree (that is, any two elements of the branch are comparable, and any element of the tree not in the branch is incomparable with at least one element of the branch). The length of a branch is the ordinal that is order isomorphic to the branch. For each ordinal $\backslash alpha$, the $\backslash alpha$th level of $T$ is the set of all elements of $T$ of height $\backslash alpha$. A tree is a $\backslash kappa$-tree, for an ordinal number $\backslash kappa$, if and only if it has height $\backslash kappa$ and every level has cardinality less than the cardinality of $\backslash kappa$. The width of a tree is the supremum of the cardinalities of its levels.

Any single-rooted tree of height $\backslash leq\; \backslash omega$ forms a meet-semilattice, where the meet (common predecessor) is given by the maximal element of the intersection of predecessors; this maximal element exists as the set of predecessors is non-empty and finite. Without a single root, the intersection of predecessors can be empty (two elements need not have common ancestors), for example $\backslash left\backslash \{a,\; b\backslash right\backslash \}$ where the elements are not comparable; while if there are infinitely many predecessors there need not be a maximal element. An example is the tree $\backslash left\backslash \{0,\; 1,\; 2,\; \backslash dots,\; \backslash omega\_0,\; \backslash omega\_0\text{'}\backslash right\backslash \}$ where $\backslash omega\_0,\; \backslash omega\_0\text{'}$ are not comparable.

A subtree of a tree is a tree where $T\text{'}\; \backslash subseteq\; T$ and $T\text{'}$ is downward closed under , i.e., if $s,\; t\; \backslash in\; T$ and then $t\; \backslash in\; T\text{'}\; \backslash implies\; s\; \backslash in\; T\text{'}$. The height of each element of a subtree equals its height in the whole tree.{{cite journal

| last1 = Gaifman | first1 = Haim | author1-link = Haim Gaifman

| last2 = Specker | first2 = E. P. | author2-link = Ernst Specker

| doi = 10.1090/S0002-9939-1964-0168484-2 | doi-access = free

| journal = Proceedings of the American Mathematical Society

| jstor = 2034337

| mr = 168484

| pages = 1–7

| title = Isomorphism types of trees

| volume = 15

| year = 1964}}. Reprinted in Ernst Specker Selecta (Springer, 1990), pp. 202–208, {{doi|10.1007/978-3-0348-9259-9_18}}. This differs from the notion of subtrees in graph theory, which often have different roots than the whole tree.

There are some fairly simply stated yet hard problems in infinite tree theory. Examples of this are the Kurepa conjecture and the Suslin conjecture. Both of these problems are known to be independent of Zermelo–Fraenkel set theory. By Kőnig's lemma, every $\backslash omega$-tree has an infinite branch. On the other hand, it is a theorem of ZFC that there are uncountable trees with no uncountable branches and no uncountable levels; such trees are known as Aronszajn trees. Given a cardinal number $\backslash kappa$, a $\backslash kappa$-Suslin tree is a tree of height $\backslash kappa$ which has no chains or antichains of size $\backslash kappa$. In particular, if $\backslash kappa$ is a singular cardinal then there exists a $\backslash kappa$-Aronszajn tree and a $\backslash kappa$-Suslin tree. In fact, for any infinite cardinal $\backslash kappa$, every $\backslash kappa$-Suslin tree is a $\backslash kappa$-Aronszajn tree (the converse does not hold). One of the equivalent ways to define a weakly compact cardinal is that it is an inaccessible cardinal $\backslash kappa$ that has the tree property, meaning that there is no $\backslash kappa$-Aronszajn tree.

The Suslin conjecture was originally stated as a question about certain total orderings but it is equivalent to the statement: Every tree of whose height is the first uncountable ordinal $\backslash omega\_1$ has an antichain of cardinality $\backslash omega\_1$ or a branch of length $\backslash omega\_1$.

If is a tree, then the reflexive closure $\backslash le$ of is a prefix order on $T$.

The converse does not hold: for example, the usual order $\backslash le$ on the set $\backslash mathbb\{Z\}$ of integers is a total and hence a prefix order, but is not a set-theoretic tree since e.g. the set has no least element.

File:An infinite tree with a non-trivial well-ordering-color.gif ({{color|#ff0000|0}},{{color|#ff0000|0}},{{color|#ff0000|0}},...) or ({{color|#008000|1}},{{color|#008000|1}},{{color|#008000|1}},...) are shown in full length. ]]

• Let $\backslash kappa$ be an ordinal number, and let $X$ be a set. Let $T$ be set of all functions $f:\backslash alpha\; \backslash mapsto\; X$ where . Define if the domain of $f$ is a proper subset of the domain of $g$ and the two functions agree on the domain of $f$. Then is a set-theoretic tree. Its root is the unique function on the empty set, and its height is $\backslash kappa$. The union of all functions along a branch yields a function from $\backslash kappa$ to $X$, that is, a generalized sequence of members of $X$. If $\backslash kappa$ is a limit ordinal, none of the branches has a maximal element ("leaf"). The picture shows an example for $\backslash kappa\; =\; \backslash omega\; \backslash cdot\; 2$ and $X\; =\; \backslash \{0,1\backslash \}$.

• Each tree data structure in computer science is a set-theoretic tree: for two nodes $m,n$, define if $n$ is a proper descendant of $m$. The notions of root, node height, and branch length coincide, while the notions of tree height differ by one.

• Infinite trees considered in automata theory (see e.g. tree (automata theory)) are also set-theoretic trees, with a tree height of up to $\backslash omega$.

• A graph-theoretic tree can be turned into a set-theoretic one by choosing a root node $r$ and defining if $m\; \backslash neq\; n$ and $m$ lies on the (unique) undirected path from $r$ to $n$.

• Each Cantor tree, each Kurepa tree, and each Laver tree is a set-theoretic tree.

• Tree (descriptive set theory)
• Continuous graph

{{reflist}}

{{refbegin}}

• {{cite book |last=Jech |first=Thomas |title=Set Theory |publisher=Springer-Verlag |year=2002 |isbn=3-540-44085-2}}
• {{cite book |last=Kunen |first=Kenneth |authorlink=Kenneth Kunen |title=Set Theory: An Introduction to Independence Proofs |publisher=North-Holland |year=1980 |isbn=0-444-85401-0}} Chapter 2, Section 5.
• {{cite book |last1=Hajnal |first1=András |authorlink1=András Hajnal |last2=Hamburger |first2=Peter |title=Set Theory |publisher=Cambridge University Press |location=Cambridge |year=1999 |isbn=9780521596671 |url=https://archive.org/details/settheory0000hajn |url-access=registration }}
• {{Cite book| last = Kechris | first = Alexander S. | authorlink = Alexander S. Kechris | title = Classical Descriptive Set Theory | others = Graduate Texts in Mathematics 156 | publisher = Springer | year = 1995 | isbn = 0-387-94374-9 | id = {{isbn|3-540-94374-9}}}}

{{refend}}

• [http://www.math.uu.nl/people/jvoosten/syllabi/logicasyllmoeder.pdf Sets, Models and Proofs] by Ieke Moerdijk and [http://www.math.uu.nl/people/jvoosten/ Jaap van Oosten], see Definition 3.1 and Exercise 56 on pp. 68–69.
• [https://web.archive.org/web/20070930230404/http://planetmath.org/encyclopedia/TreeSetTheoretic.html tree (set theoretic)] by [http://planetmath.org/?op=getuser&id=455 Henry] on [http://planetmath.org/ PlanetMath]
• [https://web.archive.org/web/20070712031425/http://planetmath.org/encyclopedia/Branch.html branch] by [http://planetmath.org/?op=getuser&id=455 Henry] on [http://planetmath.org/ PlanetMath]
• [https://web.archive.org/web/20070930231713/http://planetmath.org/encyclopedia/ExampleOfTreeSetTheoretic.htm example of tree (set theoretic)] by [http://planetmath.org/?op=getuser&id=4983 uzeromay] on [http://planetmath.org/ PlanetMath]

Category:Set theory

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