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Line 46: }}</ref> * UFA to DFA: <math>2^n</math> states, see [[Hing Leung\|Leung]],<ref name="Leung2005">{{cite journal\|last1=Leung\|first1=Hing\|title=Descriptional complexity of NFA of different ambiguity\|journal=International Journal of Foundations of Computer Science\|volume=16\|issue=055\|year=2005\|pages=975–984\|issn=0129-0541\|doi=10.1142/S0129054105003418}}</ref> An earlier lower bound by Schmidt<ref name="Schmidt1978">{{cite thesis \|type=Ph.D. \|last=Schmidt \|first=Erik M. \|date=1978 \|title=Succinctness of Description of Context-Free, Regular and Unambiguous Languages \|publisher=Cornell University}}</ref> was smaller. * NFA to UFA: <math>2^n-1</math> states, see Leung.<ref name="Leung2005" /> There was an earlier smaller lower bound by Schmidt.<ref name="Schmidt1978" /> Line 52: * SVFA to DFA: <math>\Theta(3^{n/3})</math> states, see Jirásková and [[Giovanni Pighizzini\|Pighizzini]]<ref name="JiráskováPighizzini2011">{{cite journal\|last1=Jirásková\|first1=Galina\|last2=Pighizzini\|first2=Giovanni\|title=Optimal simulation of self-verifying automata by deterministic automata\|journal=Information and Computation\|volume=209\|issue=3\|year=2011\|pages=528–535\|issn=08905401\|doi=10.1016/j.ic.2010.11.017}}</ref> * 2DFA to DFA: <math>n(n^n-(n-1)^n)</math> states, see [[Christos Kapoutsis\|Kapoutsis]].<ref name="Kapoutsis2005">{{cite journal\|last1=Kapoutsis\|first1=Christos\|title=~~Removing~~Mathematical ~~Bidirectionality~~Foundations ~~from~~of ~~Nondeterministic~~Computer ~~Finite~~Science ~~Automata~~2005\|volume=3618\|year=2005\|pages=544–555\|issn=0302-9743\|doi=10.1007/11549345_47\|chapter=Removing Bidirectionality from Nondeterministic Finite Automata\|series=Lecture Notes in Computer Science\|isbn=978-3-540-28702-5}}</ref> Earlier construction by [[John Cedric Shepherdson\|Shepherdson]]<ref name="Shepherdson1959">{{cite journal\|last1=Shepherdson\|first1=J. C.\|title=The Reduction of Two-Way Automata to One-Way Automata\|journal=IBM Journal of Research and Development\|volume=3\|issue=2\|year=1959\|pages=198–200\|issn=0018-8646\|doi=10.1147/rd.32.0198}}</ref> used more states, and an earlier lower bound by Moore<ref name="Moore1971">{{cite journal\|last1=Moore\|first1=F.R.\|title=On the Bounds for State-Set Size in the Proofs of Equivalence Between Deterministic, Nondeterministic, and Two-Way Finite Automata\|journal=IEEE Transactions on Computers\|volume=C-20\|issue=10\|year=1971\|pages=1211–1214\|issn=0018-9340\|doi=10.1109/T-C.1971.223108}}</ref> was smaller. * 2DFA to NFA: <math>\binom{2n}{n+1} = O(\frac{4^n}{\sqrt{n}})</math>, see Kapoutsis.<ref name="Kapoutsis2005" /> Earlier construction by [[Jean-Camille Birget\|Birget]] <ref name="Birget1993a">{{cite journal\|last1=Birget\|first1=Jean-Camille\|title=State-complexity of finite-state devices, state compressibility and incompressibility\|journal=Mathematical Systems Theory\|volume=26\|issue=3\|year=1993\|pages=237–269\|issn=0025-5661\|doi=10.1007/BF01371727}}</ref> used more states. Line 61: * AFA to DFA: <math>2^{2^n}</math> states, see [[Ashok K. Chandra\|Chandra]], [[Dexter Kozen\|Kozen]] and [[Larry Stockmeyer\|Stockmeyer]].<ref name="ChandraKozen1981">{{cite journal\|last1=Chandra\|first1=Ashok K.\|last2=Kozen\|first2=Dexter C.\|last3=Stockmeyer\|first3=Larry J.\|title=Alternation\|journal=Journal of the ACM\|volume=28\|issue=1\|year=1981\|pages=114–133\|issn=00045411\|doi=10.1145/322234.322243}}</ref> * AFA to NFA: <math>2^n</math> states, see Fellah, Jürgensen and Yu.<ref name="FellahJürgensen1990">{{cite journal\|last1=Fellah\|first1=A.\|last2=Jürgensen\|first2=H.\|last3=Yu\|first3=S.\|title=Constructions for alternating finite automata∗\|journal=International Journal of Computer Mathematics\|volume=35\|issue=~~1-4~~1–4\|year=1990\|pages=117–132\|issn=0020-7160\|doi=10.1080/00207169008803893}}</ref> * 2AFA to DFA: <math>2^{n2^n}</math>, see [[Richard Ladner\|Ladner]], [[Richard J. Lipton\|Lipton]] and [[Larry Stockmeyer\|Stockmeyer]].<ref name="LadnerLipton1984">{{cite journal\|last1=Ladner\|first1=Richard E.\|last2=Lipton\|first2=Richard J.\|last3=Stockmeyer\|first3=Larry J.\|title=Alternating Pushdown and Stack Automata\|journal=SIAM Journal on Computing\|volume=13\|issue=1\|year=1984\|pages=135–155\|issn=0097-5397\|doi=10.1137/0213010}}</ref> * 2AFA to NFA: <math>2^{\Theta(n \log n)}</math>, see [[Viliam Geffert\|Geffert]] and [[Alexander Okhotin\|Okhotin]].<ref name="GeffertOkhotin2014">{{cite journal\|last1=Geffert\|first1=Viliam~~\|last2=Okhotin\|first2=Alexander~~\|title=~~Transforming~~Mathematical ~~Two-Way~~Foundations ~~Alternating~~of ~~Finite~~Computer ~~Automata~~Science ~~to One-Way Nondeterministic Automata~~2014\|last2=Okhotin\|first2=Alexander\|volume=8634\|year=2014\|pages=291–302\|issn=0302-9743\|doi=10.1007/978-3-662-44522-8_25\|chapter=Transforming Two-Way Alternating Finite Automata to One-Way Nondeterministic Automata\|series=Lecture Notes in Computer Science\|isbn=978-3-662-44521-1}}</ref> ==The 2DFA vs. 2NFA problem and logarithmic space== Line 84: \| publisher = ACM \| ___location = \| pages = ~~275-286~~275–286 \| doi = 10.1145/800133.804357 }}</ref>, Line 108: \| volume = 55 \| issue = 2 \| pages = ~~421-447~~421–447 \| doi = 10.1007/s00224-013-9465-0 }}</ref> Line 134: \| journal = Soviet Mathematics Doklady \| volume = 11 \| pages = ~~1373-1375~~1373–1375 }}</ref> and by Yu, Zhuang and [[Kai Salomaa\|Salomaa]]. <ref name="YuZhuang1994">{{cite journal\|last1=Yu\|first1=Sheng\|last2=Zhuang\|first2=Qingyu\|last3=Salomaa\|first3=Kai\|title=The state complexities of some basic operations on regular languages\|journal=Theoretical Computer Science\|volume=125\|issue=2\|year=1994\|pages=315–328\|issn=03043975\|doi=10.1016/0304-3975(92)00011-F}}</ref> [[Markus Holzer\|Holzer]] and [[Martin Kutrib\|Kutrib]] <ref name="HolzerKutrib2003">{{cite journal\|last1=Holzer\|first1=Markus\|last2=Kutrib\|first2=Martin\|title=NONDETERMINISTIC DESCRIPTIONAL COMPLEXITY OF REGULAR LANGUAGES\|journal=International Journal of Foundations of Computer Science\|volume=14\|issue=066\|year=2003\|pages=1087–1102\|issn=0129-0541\|doi=10.1142/S0129054103002199}}</ref> pioneered the state complexity of operations on NFA. The known results for basic operations are listed below. Line 153: * NFA: <math>m+n+1</math> states, see Holzer and Kutrib.<ref name="HolzerKutrib2003" /> * UFA: between <math>mn+m+n</math> and <math>O(n 2^{0.79m})</math> states, see Jirásek, Jirásková and Šebej.<ref name="JirásekJirásková2016">{{cite journal\|last1=Jirásek\|first1=Jozef\|title=Developments in Language Theory\|last2=Jirásková\|first2=Galina\|last3=Šebej\|first3=Juraj~~\|title=Operations on Unambiguous Finite Automata~~\|volume=9840\|year=2016\|pages=243–255\|issn=0302-9743\|doi=10.1007/978-3-662-53132-7_20\|chapter=Operations on Unambiguous Finite Automata\|series=Lecture Notes in Computer Science\|isbn=978-3-662-53131-0}}</ref> * 2DFA: between <math>m+n</math> and <math>4m+n+4</math> states, see Kunc and Okhotin.<ref name="KuncOkhotin2012">{{cite journal\|last1=Kunc\|first1=Michal\|last2=Okhotin\|first2=Alexander\|title=State complexity of operations on two-way finite automata over a unary alphabet\|journal=Theoretical Computer Science\|volume=449\|year=2012\|pages=106–118\|issn=03043975\|doi=10.1016/j.tcs.2012.04.010}}</ref> * 2NFA: <math>m+n</math> states, see Kunc and Okhotin.<ref name="KuncOkhotin2011">{{cite journal\|last1=Kunc\|first1=Michal\|last2=Okhotin\|first2=Alexander\|title=State Complexity of Union and Intersection for Two-way Nondeterministic Finite Automata \|journal=Fundamenta Informaticae\|volume=110\|year=2011\|pages=~~231-239~~231–239\|doi=10.3233/FI-2011-540\|doi-broken-date=2017-03-22}}</ref> ===Intersection=== Line 196: * UFA: <math>\frac{3}{4} 2^{m+n}-1</math> states, see Jirásek, Jirásková and Šebej.<ref name="JirásekJirásková2016" /> * 2DFA: at least <math>\frac{2^{\Omega(n)}}{\log m}</math> and at most <math>2m^{m+1}\cdot 2^{n^{n+1}}</math> states, see Jirásková and Okhotin.<ref name="JiráskováOkhotin2008">{{cite journal\|last1=Jirásková\|first1=Galina\|title=Developments in Language Theory\|last2=Okhotin\|first2=Alexander~~\|title=On the State Complexity of Operations on Two-Way Finite Automata~~\|volume=5257\|year=2008\|pages=443–454\|issn=0302-9743\|doi=10.1007/978-3-540-85780-8_35\|chapter=On the State Complexity of Operations on Two-Way Finite Automata\|series=Lecture Notes in Computer Science\|isbn=978-3-540-85779-2}}</ref> ===Kleene star=== Line 224: was written by Yu.--> Surveys of state complexity were written by Holzer and Kutrib<ref name="HolzerKutrib2009">{{cite journal\|last1=Holzer\|first1=Markus\|last2=Kutrib\|first2=Martin\|title=Nondeterministic finite automata — recent results on the descriptional and computational complexity\|journal=International Journal of Foundations of Computer Science\|volume=20\|issue=044\|year=2009\|pages=563–580\|issn=0129-0541\|doi=10.1142/S0129054109006747}}</ref><ref name="HolzerKutrib2011">{{cite journal\|last1=Holzer\|first1=Markus\|last2=Kutrib\|first2=Martin\|title=Descriptional and computational complexity of finite automata—A survey\|journal=Information and Computation\|volume=209\|issue=3\|year=2011\|pages=456–470\|issn=08905401\|doi=10.1016/j.ic.2010.11.013}}</ref> and by Gao et al.{{cite arxiv\| eprint=1509.03254v1\| last1=Gao\| first1=Yuan\| title=A Survey on Operational State Complexity\| last2=Moreira\| first2=Nelma\| last3=Reis\| first3=Rogério\| last4=Yu\| first4=Sheng\| class=cs.FL\| year=2015}} ~~and by Gao et al.{{cite arxiv\| arxiv=1509.03254v1}}~~ New research on state complexity

State complexity: Difference between revisions