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Polynomials with Coefficients from a Division Ring

Published online by Cambridge University Press:  20 November 2018

Una Bray
Affiliation:
Smith College, Northampton, Massachusetts
George Whaples
Affiliation:
University of Massachusetts, Amherst, Massachusetts
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Let R be any division ring and let

1

be a polynomial, in the indeterminate X, with coefficients in R. Note that the powers of X are always to the right of the coefficients. We denote the set of all such polynomials by R[X].

B. Beck [3] proved the following theorem for the generalized quaternion division algebra; i.e., any division ring of dimension 4 over its center:

THEOREM 1. If f(X) is of degree n then f(X) has either infinitely many or at most n zeros in R.

Under a reasonable definition of multiplicity Beck also proved:

THEOREM 2. Let (c1, c2, …, cn) be a set of pairwise non-conjugate elements of R, and (m1, …, mN) positive integers such that Σmi = n = deg f(x).

Type
Research Article
Copyright
Copyright © Canadian Mathematical Society 1983

References

1. Artin, E., Geometric algebra (Wiley Interscience Series, 1957).Google Scholar
2. Artin, E. and Whaples, G., The theory of simple rings, American Journal of Math. 65 (1943), 87107.Google Scholar
3. Beck, B., Sur les équations polynomials dans les quaternions, L'Enseignment Math. 25.Google Scholar
4. Gordon, B. and Motzkin, T. S., On the zeros of polynomials over division rings, Trans. Amer. Math. Soc. 116 (1965), 218226, correction ibid. 122 (1966), 547.Google Scholar
5. Herstein, I. N., Conjugates in division rings, Proc. Amer. Math. Soc. 7 (1956), 10211022.Google Scholar
6. Ingraham, M. H. and Wolf, M. C., Relative linear sets and similarity of matrices whose elements belong to a division algebra, Trans. Amer. Math. Soc. 42 (1934), 1631.Google Scholar
7. Jacobson, N., The structure of rings (American Math. Society, Colloquium Publ. 37, 1956).Google Scholar
8. Jacobson, N., The theory of rings, 5th edition, Math. Survey Series No. 2 (Amer. Soc. Series, 1978).Google Scholar
9. Niven, I., Equations in quaternions, American Math. Monthly 48 (1941), 654661.Google Scholar
10. Niven, I., The roots of quaternions, American Math. Monthly 49 (1942), 386388.Google Scholar
11. Ore, O., The theory of non-commutative polynomials, Annals of Math. II 34 (1933), 480508.Google Scholar
12. Sylvester, J., Mathematical papers, Volume IV (Cambridge University Press, 1912).Google Scholar
13. Wolf, L., Simularity of matrices in which the elements are real quaternions, Bulletin of the Amer. Math. Soc. 42 (1936), 737743.Google Scholar