Victor Shestakov
This article includes a list of general references, but it lacks sufficient corresponding inline citations. (March 2015) |
Victor Shestakov | |
---|---|
Born | 1907 |
Died | 1987 |
Nationality | Soviet |
Alma mater | Moscow State University |
Scientific career | |
Fields | Mathematics, Engineering |
Doctoral advisor | Valery Glivenko |
Victor Ivanovich Shestakov (Russian: Виктор Иванович Шестаков) (1907–1987) was a Russian/Soviet logician and theoretician of electrical engineering. In 1935 he discovered the possible interpretation of Boolean algebra of logic in electro-mechanical relay circuits. He graduated from Moscow State University (1934) and worked there in the General Physics Department almost until his death.
Shestakov proposed a theory of electric switches based on Boolean logic earlier than Claude Shannon (according to certification of Soviet logicians and mathematicians Sofya Yanovskaya, M. G. Gaaze-Rapoport, Roland Dobrushin, Oleg Lupanov, Yu. A. Gastev, Yu. T. Medvedev, and Vladimir Andreevich Uspensky). However, both Shestakov and Shannon defended their theses the same year (1938),[1] and the first publication of Shestakov's result took place only in 1941 (in Russian).[1][2]
In the early 20th century, relay circuits began to be more widely used in automatics, defense of electric and communications systems.[clarification needed] Every relay circuit schema for practical use was a distinct invention, because the general principle of simulation of these systems was not known.[citation needed] Shestakov's credit (and independently later Claude Shannon's) is the general theory of logical simulation, inspired by the rapidly increasing complexity of technical demands. Logical simulation requires solid mathematical foundations. Namely these foundations were originally established by Shestakov.
Shestakov set forth an algebraic logic model of electrical two-pole switches (later three- and four-pole switches) with series and parallel connections of schematic elements (resistors, capacitors, magnets, inductive coils, etc.). Resistance of these elements could take arbitrary values on the real-number line, and upon the two-element set {0, ∞} this degenerates into the bivalent Boolean algebra of logic.
Shestakov may be considered as a forerunner of combinatorial logic and its application (and, hence, Boolean algebra of logic as well) in electric engineering, the 'language' of which is broad enough to simulate non-electrical objects of any conceivable physical nature. He was a pioneer of study of merged continual algebraic logic (parametrical) and topological (structural) models.[citation needed]
See also
[edit]References
[edit]- Shestakov, V. I. Algebra of Two Poles Schemata (Algebra of A-Schemata). In: Automatics and Telemechanics, 1941, N 2, p. 15 – 24 (Russian)
- Shestakov, V. I. Algebra of Two Poles Schemata (Algebra of A-Schemata).In: Journal of Technical Physics, 1941, Vol. 11, N 6. p. 532 – 549 (Russian)
- Bazhanov, V. A., Volgin, L. I. V. I. Shestakov and C. Shannon: the Fate of One Brilliant Idea. In: Scientific and Technical Kaleidoscope, 2001, N2, pp. 43 – 48. (Russian)
- Bazhanov, V. A. V. I. Shestakov and C. Shannon: Different Fates of One Brilliant Idea Architects[permanent dead link ]. In: Problems of History of Science and Technology, 2005, N 2, pp. 112– 121. (Russian)
- Bazhanov, V. A. History of Logic in Russia and the USSR. Moscow, Kanon+, 2007. (Russian) ISBN 5-88373-032-9
- Gaaze-Rapoport, M. G. The Making of Cybernetics in the USSR. In: Cybernetics: Past for the Future. Moscow, 1989, pp. 46–85. (Russian)
- Gastev Yu. A., Medvedev, Yu. T. Some Problems of Electric Circuits. In: History of Russian Mathematics. Kiev, 1970, Vol. 2, pp. 443 – 446. (Russian)
- Dobrushin, R. L., Lupanov, O. B. Preface to the book: Shannon, C. Works of the Theory of Information and Cybernetics. Moscow, 1963, pp. 9. (Russian)
- Yanovskaya S. A. Mathematical Logic and Foundation of Mathematics. In: Mathematics in the USSR During Last 40 Years. Moscow, 1959, Vol. 1, pp. 13 – 120. (Russian)
- Stanković, Radomir S.; Astola, Jaakko T.; Karpovsky, Mark G. (2007). Some Historical Remarks on Switching Theory. CiteSeerX 10.1.1.66.1248. S2CID 10029339.
Specific
- ^ a b Moisil, GR. C. (1969). The Algebraic Theory of Switching Circuits. Pergamon Press. pp. 12, 17. ISBN 9781483160764.
- ^ Jones, Capers (2014). The Technical and Social History of Software Engineering. Pearson Education. p. 39. ISBN 9780321903426.