László Rédei

Portrait of László Rédei

László Rédei (Rákoskeresztúr, 15 November 1900Budapest, 21 November 1980) was a Hungarian mathematician.

He graduated from the University of Budapest and initially worked as a schoolteacher. In 1940 he was appointed professor in the University of Szeged and in 1967 moved to the Mathematical Institute of the Hungarian Academy of Sciences in Budapest.

His mathematical work was in algebraic number theory and abstract algebra, especially group theory. He proved that every finite tournament contains an odd number of Hamiltonian paths. He gave several proofs of the theorem on quadratic reciprocity. He proved important results concerning the invariants of the class groups of quadratic number fields.[1] In several cases, he determined if the ring of integers of the real quadratic field Q(√d) is Euclidean or not. He successfully generalized Hajós's theorem. This led him to the investigations of lacunary polynomials over finite fields, which he eventually published in a book. This work on lacunary polynomials has had a big influence in the field of finite geometry where it plays an important role in the theory of blocking sets. He introduced a very general notion of skew product of groups, both the Schreier-extension and the Zappa–Szép product are special case of. He explicitly determined those finite noncommutative groups whose all proper subgroups were commutative (1947). This is one of the very early results which eventually led to the classification of all finite simple groups.

He was the president of the János Bolyai Mathematical Society (19471949). He was awarded the Kossuth Prize twice. He was elected corresponding member (1949), full member (1955) of the Hungarian Academy of Sciences.

His books

References

  1. Engstrom, Howard Theodore (1937). "Review: Sur les Classes d'Idéaux dans les Corps Quadratiques by S. Iyanaga" (PDF). Bull. Amer. Math. Soc. 43 (1): 12–13. doi:10.1090/s0002-9904-1937-06477-9. Iyanaga's pamphlet discusses and generalizes one of Rédei's theorems; it gives a "necessary and sufficient condition for the existence of an ideal class (in the restricted sense) of order 4 in a quadratic field k(√D) ..."

External links


This article is issued from Wikipedia - version of the 10/21/2016. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.