Regular Language: Difference between revisions

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(New page: {{subpages}} In computing theory, a regular language is one that is accepted by a finite automaton. == Closure Properties == Suppose <math>A, B \subseteq \Sigma^*</math> are reg...)
 
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In computing theory, a regular [[language]] is one that is accepted by a [[finite automaton]].
In computing theory, a '''regular [[language]]''' is one that is accepted by a [[finite automaton]].
 
== Equivalent Characterizations ==
 
* <math>A</math> is a regular language.
* <math>A</math> is accepted by a [[deterministic finite automaton]](DFA).
* <math>A</math> is accepted by an [[alternating finite automaton]](AFA).
* <math>A</math> is accepted by a [[non-deterministic finite automaton]](NFA).
* <math>A</math> is accepted by a [[generalized non-deterministic finite automaton]](GNFA).
* <math>A</math> can be described by a [[regular expression]](RE).


== Closure Properties ==
== Closure Properties ==
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Suppose <math>A, B \subseteq \Sigma^*</math> are regular languages.  Then the following languages are also regular.
Suppose <math>A, B \subseteq \Sigma^*</math> are regular languages.  Then the following languages are also regular.


* <math>A \cup B = \{x ~|~ x \in A</math> or <math>x \in B\}</math> ([[union]])
* <math>A \cup B = \{x ~|~ x \in A\ \mathrm{or}\ x \in B\}</math> ([[union]])
* <math>A \cap B = \{x ~|~ x \in A</math> and <math>x \in B\}</math> ([[intersection]])
* <math>A \cap B = \{x ~|~ x \in A\ \mathrm{and}\ x \in B\}</math> ([[intersection]])
* <math>\bar{A} = \{x \in \Sigma^* ~|~ x \not\in A\}</math> ([[complement]])
* <math>\bar{A} = \{x \in \Sigma^* ~|~ x \not\in A\}</math> ([[complement (computer language)]])
* <math>AB = \{xy ~|~ x \in A</math> and <math>y \in B\}</math> ([[concatenation]])
* <math>AB = \{xy ~|~ x \in A\ \mathrm{and}\ y \in B\}</math> ([[concatenation]])
* <math>A^* = \{x_1 x_2 \ldots x_n ~|~ n \geq 0</math> and <math>x_i \in A,~1 \leq i \leq n\}</math> ([[asterate]])
* <math>A^* = \{x_1 x_2 \ldots x_n ~|~ n \geq 0\ \mathrm{and}\ x_i \in A,~1 \leq i \leq n\}</math> ([[asterate]])
* <math>A - B = \{x - y ~|~ x \in A\ \mathrm{and}\ y \in B\}</math> ([[difference]])
* <math>A^R = \{x^R|~ x \in A\ \}</math> ([[reversal]])


Regular languages are also closed under homomorphic images and preimages.  Suppose <math>C \subseteq \Gamma^*</math> is a regular language and <math>h : \Sigma^* \to \Gamma^*</math> is a [[string homomorphism]].  Then the following languages are regular.
Regular languages are also closed under homomorphic images and preimages.  Suppose <math>C \subseteq \Gamma^*</math> is a regular language and <math>h : \Sigma^* \to \Gamma^*</math> is a [[string homomorphism]].  Then the following languages are regular.


* <math>h(A) = \{h(x) ~|~ x \in A\} \subseteq \Gamma^*</math> (homomorphic [[image]])
* <math>h(A) = \{h(x) ~|~ x \in A\} \subseteq \Gamma^*</math> (homomorphic [[image]])
* <math>h^{-1}(C) = \{x ~|~ h(x) \in C\} \subseteq \Sigma^*</math> (homomorphic [[preimage]])
* <math>h^{-1}(C) = \{x ~|~ h(x) \in C\} \subseteq \Sigma^*</math> (homomorphic [[preimage]])[[Category:Suggestion Bot Tag]]

Latest revision as of 16:01, 10 October 2024

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In computing theory, a regular language is one that is accepted by a finite automaton.

Equivalent Characterizations

Closure Properties

Suppose are regular languages. Then the following languages are also regular.

  • (union)
  • (intersection)
  • (complement (computer language))
  • (concatenation)
  • (asterate)
  • (difference)
  • (reversal)

Regular languages are also closed under homomorphic images and preimages. Suppose is a regular language and is a string homomorphism. Then the following languages are regular.

  • (homomorphic image)
  • (homomorphic preimage)