Avraham Trahtman

Avraham Naumovich Trahtman (Trakhtman) (Russian: Абрам Наумович Трахтман; b. 1944, USSR) is a mathematician at Bar-Ilan University (Israel). In 2007, Trahtman solved a problem in combinatorics that had been open for 37 years, the Road Coloring Conjecture posed in 1970.[1]

Avraham Naumovich Trahtman
Born10 February 1944
Alma materUral State University
Known forsolving the road coloring problem
Scientific career
FieldsMathematics
InstitutionsBar-Ilan University
Doctoral advisorLev N. Shevrin

Road coloring problem posed and solved

Trahtman's solution to the road coloring problem was accepted in 2007 and published in 2009 by the Israel Journal of Mathematics.[2] The problem arose in the subfield of symbolic dynamics, an abstract part of the field of dynamical systems. The road coloring problem was raised by R. L. Adler and L. W. Goodwyn from the United States, and the Israeli mathematician B. Weiss.[3][4] The proof used results from earlier work.[5][6][7]

Černý conjecture

The problem of estimating the length of synchronizing word has a long history and was posed independently by several authors, but it is commonly known as the Černý conjecture. In 1964 Jan Černý conjectured that is the upper bound for the length of the shortest synchronizing word for any n-state complete DFA (a DFA with complete state transition graph).[8] If this is true, it would be tight: in his 1964 paper, Černý exhibited a class of automata (indexed by the number n of states) for which the shortest reset words have this length. In 2011 Trahtman published a proof[9] of upper bound , but then he found an error in it.[10] The conjecture holds in many partial cases, see for instance, Kari[11] and Trahtman.[12]

Other work

The finite basis problem for semigroups of order less than six in the theory of semigroups was posed by Alfred Tarski in 1966,[13] and repeated by Anatoly Maltsev and L. N. Shevrin. In 1983, Trahtman solved this problem by proving that all semigroups of order less than six are finitely based.[14][15]

In the theory of varieties of semigroups and universal algebras the problem of existence of covering elements in the lattice of varieties was posed by Evans in 1971.[16] The positive solution of the problem was found by Trahtman.[17] He also found a six-element semigroup that generates a variety with a continuum of subvarieties,[18] and varieties of semigroups having no irreducible base of identities.[19]

The theory of locally testable automata can be based on the theory of varieties of locally testable semigroups.[20] Trahtman found the precise estimation on the order of local testability of finite automata.[21]

There are results in theoretical mechanics[22] and in the promising area of extracting moisture from the air[23] mentioned in "New Scientist".[24]

gollark: Ah.
gollark: What BSA would be fitting? I can't think of any, especially ones of actual use.
gollark: I wonder whether the spotted ones will end up hunted into extreme rarity like aeons.
gollark: I suspect the true figure is more like 6000 universe cycles.
gollark: ~60 octillion years.

References

  1. J.E. Pin. On two combinatorial problems arising from automata theory. Annals of Discrete Math., 17, 535-548, 1983.
  2. Avraham N. Trahtman: The Road Coloring Problem. Israel Journal of Mathematics, Vol. 172, 5160, 2009
  3. R.L. Adler, B. Weiss. Similarity of automorphisms of the torus, Memoirs of the Amer. Math. Soc. 98, Providence, RI, 1970
  4. R.L. Adler, L.W. Goodwyn, B. Weiss. Equivalence of topological Markov shifts, Israel J. of Math. 27, 49-63, 1977
  5. K. Culik II, J. Karhumaki, J. Kari. A note on synchronized automata and Road Coloring Problem. Developments in Language Theory (5th Int. Conf., Vienna, 2001), Lecture Notes in Computer Science, 2295, 175-185, 2002
  6. J. Friedman. On the road coloring problem. Proc. of the Amer. Math. Soc. 110, 1133-1135, 1990
  7. A.N. Trahtman. An Algorithm for Road Coloring. Lect. Notes in Comp. Sci, 7056 (2011), Springer, 349--360
  8. J. Černý, Poznamka k homogenym eksperimentom s konechnymi automatami, Math.-Fyz. Čas., 14(1964) 208--215.
  9. A.N. Trahtman. Modifying the Upper Bound on the Length of Minimal Synchronizing Word. Lect. Notes in Comp. Sci, 6914(2011) Springer, 173-180
  10. Trahtman, A. N (2011). "Modifying the upper bound on the length of minimal synchronizing word". arXiv:1104.2409v6 [cs.DM].
  11. J. Kari. Synchronizing finite automata on Eulerian digraphs. Springer, Lect. Notes in Comp. Sci., 2136, 432-438, 2001.
  12. A.N. Trahtman. The Černý Conjecture for Aperiodic Automata. Discrete Math. Theor. Comput. Sci. v. 9, 2(2007), 3-10
  13. A. Tarski. Equational logic and equational theories of algebras. Contrib. to math. Logic. Hannover, 1966, (Amst. 1968), 275-288.
  14. A. N. Trahtman. The finite basis question for semigroups of order less than six. Semigroup Forum, 27(1983), 387-389.
  15. A.N. Trahtman. Finiteness of a basis of identities of 5-element semigroups. Polugruppy i ih gomomorphismy, Ross. Gos. ped. Univ., Leningrad, 1991, 76-98.
  16. T. Evans. The lattice of semigroup varieties. Semigroup Forum. 2, 1(1971), 1-43.
  17. A.N. Trahtman. Covering elements in the lattice of varieties of universal algebras. Mat. Zametky, Moscow, 15(1974), 307-312.
  18. A.N. Trahtman. A six-element semigroup that generates a variety with a continuum of subvarieties. Ural Gos. Univ. Mat. zap., Alg. syst. i ih mnogoobr., Sverdlovsk, 14(1988), no. 3, 138-143.
  19. A. N. Trahtman. A variety of semigroups without an irreducible basis of identities. Math. Zametky, Moscow, 21(1977), 865-871.
  20. A. N. Trahtman. Identities of locally testable semigroups. Comm. Algebra, 27(1999), no. 11, 5405-5412.
  21. A. N. Trahtman. Optimal estimation on the order of local testability of finite automata. Theoret. Comput. Sci., 231(2000), 59-74.
  22. S.A. Kazak, G.G. Kozhushko, A.N. Trahtman. Calculation of load in discrete chains. Teorija mashin i met. gorn. ob. Sverdlovsk, rel. 1, 1978, 39-51.
  23. B Kogan., A.N. Trahtman. The Moisture from the Air as Water Resource in Arid Region: Hopes, Doubts and Facts. J of Arid Env., London, 2, 53(2003), 231-240.
  24. F. Pearce. Pyramids of dew. "New Scientist". 16 April 2005. 52-53.
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