[en] The binomial coefficient of two words $u$ and $v$ is the number of times $v$ occurs as a subsequence of $u$. Based on this classical notion, we introduce the $m$-binomial equivalence of two words refining the abelian equivalence. Two words $x$ and $y$ are $m$-binomially equivalent, if, for all words $v$ of length at most $m$, the binomial coefficients of $x$ and $v$ and respectively, $y$ and $v$ are equal. The $m$-binomial complexity of an infinite word $x$ maps an integer $n$ to the number of $m$-binomial equivalence classes of factors of length $n$
occurring in $x$. We study the first properties of $m$-binomial equivalence. We compute the $m$-binomial complexity of two classes of words: Sturmian words and (pure) morphic words that are fixed points of Parikh-constant morphisms like the Thue--Morse word, i.e., images by the morphism of all the letters have the same Parikh vector. We prove that the frequency of each symbol of an infinite recurrent word with bounded $2$-binomial complexity is rational.
Disciplines :
Mathematics
Author, co-author :
Rigo, Michel ; Université de Liège - ULiège > Département de mathématique > Mathématiques discrètes
Salimov, Pavel
Language :
English
Title :
Another Generalization of Abelian Equivalence: Binomial Complexity of Infinite Words (long version)
Publication date :
2015
Journal title :
Theoretical Computer Science
ISSN :
0304-3975
Publisher :
Elsevier Science, Amsterdam, Netherlands
Special issue title :
WORDS 2013
Volume :
601
Pages :
47-57
Peer reviewed :
Peer Reviewed verified by ORBi
Commentary :
This is an extended version of the conference version. In particular, it contains a new discussion about frequencies of symbols when the $2$-binomial complexity is bounded.
scite shows how a scientific paper has been cited by providing the context of the citation, a classification describing whether it supports, mentions, or contrasts the cited claim, and a label indicating in which section the citation was made.
Bibliography
Adamczewski B. Balances for fixed points of primitive substitutions. Theoret. Comput. Sci. 2003, 307:47-75.
Avgustinovich S.V., Fon-Der-Flaass D.G., Frid A.E. Arithmetical complexity of infinite words. Words, Languages & Combinatorics III 2003, 51-62. World Scientific Publishing. M. Ito, T. Imaoka (Eds.).
Brlek S. Enumeration of factors in the Thue-Morse word. Discrete Appl. Math. 1989, 24:83-96.
Berstel J., Crochemore M., Pin J.-E. Thue-Morse sequence and p-adic topology for the free monoid. Discrete Math. 1989, 76:89-94.
Cassaigne J. Complexité et facteurs spéciaux. Bull. Belg. Math. Soc. Simon Stevin 1997, 4:67-88.
Cobham A. Uniform tag sequences. Math. Syst. Theory 1972, 6:164-192.
de Luca A., Varricchio S. On the factors of the Thue-Morse word on three symbols. Inform. Process. Lett. 1988, 27:281-285.
Ehrenfeucht A., Rozenberg G. A limit theorem for sets of subwords in deterministic TOL languages. Inform. Process. Lett. 1973, 2:70-73.
Ehrenfeucht A., Lee K.P., Rozenberg G. Subword complexities of various classes of deterministic developmental languages without interactions. Theoret. Comput. Sci. 1975, 1:59-75.
Kamae T., Zamboni L. Sequence entropy and the maximal pattern complexity of infinite words. Ergodic Theory Dynam. Systems 2002, 22:1191-1199.
Karhumäki J., Saarela A., Zamboni L.Q. On a generalization of Abelian equivalence and complexity of infinite words. J. Combin. Theory Ser. A 2013, 120:2189-2206.
Lothaire M. Combinatorics on Words, Cambridge Mathematical Library 1997, Cambridge University Press.
Lothaire M. Algebraic Combinatorics on Words. Encyclopedia of Mathematics and Its Applications 2002, vol. 90. Cambridge University Press.
Lothaire M. Applied Combinatorics on Words. Encyclopedia of Mathematics and Its Applications 2005, vol. 105. Cambridge University Press.
Mateescu A., Salomaa A., Salomaa K., Yu S. A sharpening of the Parikh mapping. Theor. Inform. Appl. 2001, 35:551-564.
Mateescu A., Salomaa A., Yu S. Subword histories and Parikh matrices. J. Comput. System Sci. 2004, 68:1-21.
Pytheas Fogg N. Substitutions in dynamics, arithmetics and combinatorics. Lecture Notes in Mathematics 2002, vol. 1794. Springer-Verlag, Berlin.
Rao M., Rigo M., Salimov P. Avoiding 2-binomial squares and cubes arxiv:1310.4743.
Richomme G., Saari K., Zamboni L.Q. Balance and abelian complexity of the Tribonacci word. Adv. in Appl. Math. 2010, 45:212-231.
Richomme G., Saari K., Zamboni L.Q. Abelian complexity of minimal subshifts. J. Lond. Math. Soc. 2011, 83:79-95.
Rigo M., Salimov P. Another generalization of abelian equivalence: binomial complexity of infinite words. Lecture Notes in Computer Science 2013, vol. 8079:217-228. Springer-Verlag.
Similar publications
Sorry the service is unavailable at the moment. Please try again later.
This website uses cookies to improve user experience. Read more
Save & Close
Accept all
Decline all
Show detailsHide details
Cookie declaration
About cookies
Strictly necessary
Performance
Strictly necessary cookies allow core website functionality such as user login and account management. The website cannot be used properly without strictly necessary cookies.
This cookie is used by Cookie-Script.com service to remember visitor cookie consent preferences. It is necessary for Cookie-Script.com cookie banner to work properly.
Performance cookies are used to see how visitors use the website, eg. analytics cookies. Those cookies cannot be used to directly identify a certain visitor.
Used to store the attribution information, the referrer initially used to visit the website
Cookies are small text files that are placed on your computer by websites that you visit. Websites use cookies to help users navigate efficiently and perform certain functions. Cookies that are required for the website to operate properly are allowed to be set without your permission. All other cookies need to be approved before they can be set in the browser.
You can change your consent to cookie usage at any time on our Privacy Policy page.
