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{{BLP sources|date=August 2012}} | |||
{{inline citations|date=August 2012}} | |||
{{eastern name order|Pyber László}} | |||
'''László Pyber''' (born 8 May 1960 in [[Budapest]]) is a Hungarian mathematician. | |||
He works in [[combinatorics]] and [[group theory]]. He is a researcher at the [[Alfréd Rényi Institute of Mathematics]], Budapest.He received the title the Doctor of Science from the [[Hungarian Academy of Sciences]] (1998). He won the Academics Prize (2007). | |||
== Main results== | |||
* He proved the conjecture of [[Paul Erdős]] and [[Tibor Gallai]], that the edges of any [[Graph (mathematics)#Simple graph|simple graph]] with ''n'' vertices can be covered with at most ''n''-1 circuits and edges. | |||
* He proved the following conjecture [[Paul Erdős]]. Any graph with ''n'' vertices and its complement can be covered with ''n''<sup>2</sup>/4+2 [[Clique (graph theory)|cliques]]. | |||
* He proved a ''c''log<sup>2</sup>''n'' bound to the size of a minimal base of a [[primitive permutation group]] of degree ''n'' not containing [[Alternating group|''A''<sub>''n''</sub>]]. | |||
* He gave the following estimate of the number of groups of order ''n''. If the prime power decomposition of ''n'' is ''n''=''p''<sub>1</sub><sup>''g''<sub>1</sub></sup> ⋯ ''p''<sub>''k''</sub><sup>''g''<sub>''k''</sub></sup> and μ=max(''g''<sub>1</sub>,...,''g''<sub>k</sub>), then the number of nonisomporphic ''n''-element groups is at most | |||
<center><math>n^{(\frac{2}{27}+o(1))\mu^2}.</math></center> | |||
* [[Tomasz Łuczak|Łuczak]] and Pyber proved the following conjecture of [[John McKay (mathematician)|McKay]]. For every, ε>0 there is a number ''c'' such that for all sufficiently large ''n'', ''c'' randomly chosen elements generate the [[symmetric group]] ''S''<sub>''n''</sub> with probability greater than 1-ε. | |||
* A result also proved by Łuczak and Pyber states that almost every element of ''S''<sub>''n''</sub> does not belong to a [[Transitive_subgroup#transitive|transitive subgroup]] different from ''S''<sub>''n''</sub> and ''A''<sub>''n''</sub> (conjectured by [[Peter Cameron (mathematician)|Cameron]]). | |||
<!--* Felállította azt a sejtést, hogy majdnem minden véges csoport nilpotens. Ha ez igaz, akkor a legtöbb véges csoport 2-csoport.--> | |||
* Solving a problem of subgroup growth he proved that for every nondecreasing function ''g''(''n'')≤log(''n'') there is a [[residually finite group]] generated by 4 element, whose growth type is <math>n^{g(n)}</math>. | |||
==Selected papers== | |||
* L. Pyber: An Erdős-Gallai conjecture, ''[[Combinatorica]]'', '''5'''(1985), 67–79. | |||
* L. Pyber: Clique covering of graphs, ''[[Combinatorica]]'', '''6'''(1986), 393–398. | |||
* L. Pyber: Enumerating finite groups of given order, ''[[Annals of Mathematics]]'', (2), '''137'''(1993), 203–220. | |||
* L. Pyber: On the orders of doubly transitive permutation groups, elementary estimates, ''[[Journal of Combinatorial Theory|J. Combin. Theory]]'', (A), '''62'''(1993), 361–366. | |||
* L. Pyber: Groups of intermediate subgroup growth and a problem of Grothendieck, ''[[Duke Mathematical Journal|Duke Math. J.]]'', '''121'''(2004), 169–188. | |||
* A. Jaikin-Zapirain, L. Pyber: [http://pjm.math.berkeley.edu/annals/ta/100111-JaikinZapirain/100111-JaikinZapirain-v1.pdf Random generation of finite and profinite groups and group enumeration], to appear in ''Annals of Mathematics''. | |||
==External links== | |||
*Pyber's [http://www.renyi.hu/~pyber/ home page]. | |||
*Pyber's [http://www.mta.hu/index.php?id=1987&LANG=h&TID=1089&cHash=4cc77928ed nomination] for [[Hungarian Academy of Sciences]] membership | |||
*{{MathGenealogy|id=132736}} | |||
{{Persondata <!-- Metadata: see [[Wikipedia:Persondata]]. --> | |||
| NAME =Pyber, Laszlo | |||
| ALTERNATIVE NAMES = | |||
| SHORT DESCRIPTION = Hungarian mathematician | |||
| DATE OF BIRTH = May 8, 1960 | |||
| PLACE OF BIRTH = | |||
| DATE OF DEATH = | |||
| PLACE OF DEATH = | |||
}} | |||
{{DEFAULTSORT:Pyber, Laszlo}} | |||
[[Category:Combinatorialists]] | |||
[[Category:Group theorists]] | |||
[[Category:Hungarian mathematicians]] | |||
[[Category:Living people]] | |||
[[Category:1960 births]] | |||
Revision as of 01:00, 23 October 2013
Template:BLP sources Template:Inline citations Template:Eastern name order László Pyber (born 8 May 1960 in Budapest) is a Hungarian mathematician. He works in combinatorics and group theory. He is a researcher at the Alfréd Rényi Institute of Mathematics, Budapest.He received the title the Doctor of Science from the Hungarian Academy of Sciences (1998). He won the Academics Prize (2007).
Main results
- He proved the conjecture of Paul Erdős and Tibor Gallai, that the edges of any simple graph with n vertices can be covered with at most n-1 circuits and edges.
- He proved the following conjecture Paul Erdős. Any graph with n vertices and its complement can be covered with n2/4+2 cliques.
- He proved a clog2n bound to the size of a minimal base of a primitive permutation group of degree n not containing An.
- He gave the following estimate of the number of groups of order n. If the prime power decomposition of n is n=p1g1 ⋯ pkgk and μ=max(g1,...,gk), then the number of nonisomporphic n-element groups is at most
- Łuczak and Pyber proved the following conjecture of McKay. For every, ε>0 there is a number c such that for all sufficiently large n, c randomly chosen elements generate the symmetric group Sn with probability greater than 1-ε.
- A result also proved by Łuczak and Pyber states that almost every element of Sn does not belong to a transitive subgroup different from Sn and An (conjectured by Cameron).
- Solving a problem of subgroup growth he proved that for every nondecreasing function g(n)≤log(n) there is a residually finite group generated by 4 element, whose growth type is .
Selected papers
- L. Pyber: An Erdős-Gallai conjecture, Combinatorica, 5(1985), 67–79.
- L. Pyber: Clique covering of graphs, Combinatorica, 6(1986), 393–398.
- L. Pyber: Enumerating finite groups of given order, Annals of Mathematics, (2), 137(1993), 203–220.
- L. Pyber: On the orders of doubly transitive permutation groups, elementary estimates, J. Combin. Theory, (A), 62(1993), 361–366.
- L. Pyber: Groups of intermediate subgroup growth and a problem of Grothendieck, Duke Math. J., 121(2004), 169–188.
- A. Jaikin-Zapirain, L. Pyber: Random generation of finite and profinite groups and group enumeration, to appear in Annals of Mathematics.
External links
- Pyber's home page.
- Pyber's nomination for Hungarian Academy of Sciences membership
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