Star-free language

In theoretical computer science and formal language theory, a regular language is said to be star-free if it can be described by a regular expression constructed from the letters of the alphabet, the empty word, the empty set symbol, all boolean operators – including complementation – and concatenation but no Kleene star.^[1] The condition is equivalent to having generalized star height zero.

For instance, the language $\Sigma ^{*}$ of all finite words over an alphabet $\Sigma$ can be shown to be star-free by taking the complement of the empty set, $\Sigma ^{*}={\bar {\emptyset }}$ . Then, the language of words over the alphabet $\{a,\,b\}$ that do not have consecutive a's can be defined as ${\overline {\Sigma ^{*}aa\Sigma ^{*}}}$ , first constructing the language of words consisting of $aa$ with an arbitrary prefix and suffix, and then taking its complement, which must be all words which do not contain the substring $aa$ .

An example of a regular language which is not star-free is $(aa)^{*}$ ,^[2] i.e. the language of strings consisting of an even number of "a". For $(ab)^{*}$ where $a\neq b$ , the language can be defined as $\Sigma ^{*}\setminus (b\Sigma ^{*}\cup \Sigma ^{*}a\cup \Sigma ^{*}aa\Sigma ^{*}\cup \Sigma ^{*}bb\Sigma ^{*})$ , taking the set of all words and removing from it words starting with $b$ , ending in $a$ or containing $aa$ or $bb$ . However, when $a=b$ , this definition does not create $(aa)^{*}$ .

Marcel-Paul Schützenberger characterized star-free languages as those with aperiodic syntactic monoids.^[3]^[4] They can also be characterized logically as languages definable in FO[<], the first-order logic over the natural numbers with the less-than relation,^[5] as languages accepted by some aperiodic finite-state automaton (known as counter-free languages),^[6] and as languages definable in linear temporal logic.^[7]

All star-free languages are in uniform AC⁰.

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Star-free language

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References

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