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Line 1: {{Short description\|Theorem in order theory and lattice theory}} ~~{{Unreferenced\|date=December 2011}}~~ {{otheruses4\|Kleene's fixed-point theorem in lattice theory\|the fixed-point theorem in computability theory\|Kleene's recursion theorem}} [[File:Kleene fixpoint svg.svg\|thumb\|Computation of the least fixpoint of ''f''(''x'') = {{sfrac\|1\|10}}''x''<sup>2</sup>+[[arctangent\|atan]](''x'')+1 using Kleene's theorem in the real [[interval (mathematics)\|interval]] [0,7] with the usual order]] In the [[mathematics\|mathematical]] areas of [[order theory\|order]] and [[lattice theory]], the '''Kleene fixed-point theorem''', named after American mathematician [[Stephen Cole Kleene]], states the following: :''~~Let~~'Kleene Fixed-Point Theorem.''' Suppose <math>(L, be\sqsubseteq)</math> is a [[complete partial order\|directed-complete partial order]] (dcpo) with a least element, and let <math>f~~ ~~:~~ ~~ L~~ → ~~ \to L</math> be a [[Scott continuity\|Scott-continuous]] (and therefore [[monotone function\|monotone]]) [[function (mathematics)\|function]]. Then <math>f</math> has a [[least fixed point]], which is the [[supremum]] of the ascending Kleene chain of <math>f.</math> The '''ascending Kleene chain''' of ''f'' is the [[chain (order theory)\|chain]] :<math>\bot \; \lesqsubseteq \; f(\bot) \~~; \le \;~~sqsubseteq f~~\left~~(f(\bot)~~\right~~) \;sqsubseteq \lecdots \~~; \dots \; \le \;~~sqsubseteq f^n(\bot) \~~; \le \;~~sqsubseteq \~~dots~~cdots</math> obtained by [[iterated function\|iterating]] ''f'' on the [[least element]] ⊥ of ''L''. Expressed in a formula, the theorem states that Line 14 ⟶ 16: where <math>\textrm{lfp}</math> denotes the least fixed point. ~~This result is often attributed to [[Alfred Tarski]], but~~Although [[Tarski's fixed point theorem]] ~~pertains to [[monotone function]]s on [[complete lattices]].~~ does not consider how fixed points can be computed by iterating ''f'' from some seed (also, it pertains to [[monotone function]]s on [[complete lattices]]), this result is often attributed to [[Alfred Tarski]] who proves it for additive functions.<ref>{{cite journal \| author=Alfred Tarski \| url=http://projecteuclid.org/Dienst/UI/1.0/Summarize/euclid.pjm/1103044538 \| title=A lattice-theoretical fixpoint theorem and its applications \| journal = [[Pacific Journal of Mathematics]] \| volume=5 \| year=1955 \| issue=2 \| pages=285–309\| doi=10.2140/pjm.1955.5.285 }}, page 305.</ref> Moreover, the Kleene fixed-point theorem can be extended to [[monotone function]]s using transfinite iterations.<ref>{{cite journal \| author=Patrick Cousot and Radhia Cousot \| url=https://projecteuclid.org/euclid.pjm/1102785059 \| title=Constructive versions of Tarski's fixed point theorems \| journal = Pacific Journal of Mathematics \| volume=82 \| year=1979 \| issue=1 \| pages=43–57\| doi=10.2140/pjm.1979.82.43 }}</ref> == Proof == Source:<ref>{{Cite book\|title=Mathematical Theory of Domains by V. Stoltenberg-Hansen\|last1=Stoltenberg-Hansen\|first1=V.\|last2=Lindstrom\|first2=I.\|last3=Griffor\|first3=E. R.\|publisher=Cambridge University Press\|year=1994\|isbn=0521383447\|pages=[https://archive.org/details/mathematicaltheo0000stol/page/24 24]\|language=en\|doi=10.1017/cbo9781139166386\|url=https://archive.org/details/mathematicaltheo0000stol/page/24}}</ref> We first have to show that the ascending Kleene chain of ''<math>f''</math> exists in <math>L</math>. To show that, we prove the following ~~lemma~~:▼ :'''Lemma 1:.''' If <math>L</math> is ~~CPO~~a dcpo with a least element, and <math>f~~ ~~:~~ ~~ L~~ → ~~ \to L</math> is a Scott-continuous, then <math>f^n(\bot) \lesqsubseteq f^{n+1}(\bot), n \in \mathbb{N}_0</math>▼ ▲We first have to show that the ascending Kleene chain of ''f'' exists in L. To show that, we prove the following lemma: :'''Proof.''' byWe use induction: ▼ ▲:Lemma 1:''If L is CPO, and f : L → L is a Scott-continuous, then <math>f^n(\bot) \le f^{n+1}(\bot), n \in \mathbb{N}_0</math> :* Assume n = 0. Then <math>f^0(\bot) = \bot \~~leq~~sqsubseteq f^1(\bot),</math>, since ⊥<math>\bot</math> is the least element.▼ :* Assume n > 0. Then we have to show that <math>f^n(\bot) \~~leq~~sqsubseteq f^{n+1}(\bot)</math>. By rearranging we get <math>f(f^{n-1}(\bot)) \~~leq~~sqsubseteq f(f^n(\bot))</math>. By inductive assumption, we know that <math>f^{n-1}(\bot) \~~leq~~sqsubseteq f^n(\bot)</math> holds, and because f is monotone (property of Scott-continuous functions), the result holds as well.▼ ~~Immediate~~As a corollary of the Lemma 1we ishave the ~~existence~~following ~~of the~~directed ω-chain.:▼ ▲Proof by induction: ▲* Assume n = 0. Then <math>f^0(\bot) = \bot \leq f^1(\bot)</math>, since ⊥ is the least element. ▲* Assume n > 0. Then we have to show that <math>f^n(\bot) \leq f^{n+1}(\bot)</math>. By rearranging we get <math>f(f^{n-1}(\bot)) \leq f(f^n(\bot))</math>. By inductive assumption, we know that <math>f^{n-1}(\bot) \leq f^n(\bot)</math> holds, and because f is monotone (property of Scott-continuous functions), the result holds as well. :<math>\mathbb{M} = \{ \bot, f(\bot), f(f(\bot)), \ldots\}.</math> ▲Immediate corollary of Lemma 1 is the existence of the chain. ~~Let <math>\mathbb{M}</math> be~~From the ~~set~~definition of ~~all~~a ~~elements~~dcpo ofit ~~the~~follows ~~chain:~~that <math>\mathbb{M~~} = \{ \bot, f(\bot), f(f(\bot)), \ldots\~~}</math>~~. This set is clearly directed due to Lemma 1. From definition of CPO follows that this set~~ has a supremum, ~~we will~~ call it <math>m.</math>. What remains now is to show that <math>m</math> is the least fixed-point. First, we show that <math>m</math> is a fixed point~~. That is~~, ~~we have to show~~i.e. that <math>f(m) = m</math>. Because <math>f</math> is [[Scott continuity\|Scott-continuous]], <math>f(\sup(\mathbb{M})) = \sup(f(\mathbb{M}))</math>, that is <math>f(m) = \sup(f(\mathbb{M}))</math>. Also, since <math>\mathbb{M} = f(\mathbb{M})\cup\{\bot\}</math> and because <math>\bot</math> has no influence in determining the supremum we have: <math>\sup(f(\mathbb{M})) = \sup(\mathbb{M})</math>. ~~(from the property of the chain) and~~It ~~from~~follows that <math>f(m) = m</math>, making <math>m</math> a fixed-point of <math>f</math>. The proof that <math>m</math> is in fact the ''least'' fixed point can be done by showing that any ~~Element~~element in <math>\mathbb{M}</math> is smaller than any fixed-point of <math>f</math> (because by property of [[supremum]], if all elements of a set <math>D \subseteq L</math> are smaller than an element of <math>L</math> then also <math>\sup(D)</math> is smaller than that same element of <math>L</math>). This is done by induction: Assume <math>k</math> is some fixed-point of <math>f</math>. We now ~~proof~~prove by induction over <math>i</math> that <math>\forall i \in \mathbb{N}~~\colon~~: f^i(\bot) \sqsubseteq k</math>. ~~For~~The base of the induction ~~start, we take~~ <math>(i = 0)</math> obviously holds: <math>f^0(\bot) = \bot \sqsubseteq k,</math> ~~obviously holds,~~ since <math>\bot</math> is the ~~smallest~~least element of <math>L</math>. As the induction hypothesis, we may assume that <math>f^i(\bot) \sqsubseteq k</math>. We now do the induction step: From the induction hypothesis and the monotonicity of <math>f</math> (again, implied by the Scott-continuity of <math>f</math>), we may conclude the following: <math>f^i(\bot) \sqsubseteq k ~\implies~ f^{i+1}(\bot) \sqsubseteq f(k).</math>. Now, by the assumption that <math>k</math> is a fixed-point of <math>f,</math>, we know that <math>f(k) = k,</math>, and from that we get <math>f^{i+1}(\bot) \sqsubseteq k.</math>. == See also == * [[Knaster–Tarski theorem]] * Other [[fixed-point theorem]]s == References == {{Reflist}} [[Category:Order theory]] [[Category:Fixed-point theorems]]