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Strong Boundedness and Strong Convergence in Sequence Spaces

Published online by Cambridge University Press:  20 November 2018

Martin Buntinas
Affiliation:
Department of Mathematical Sciences, Loyola University of Chicago, Chicago, Illinois 60626, USA
Naza Tanović-Miller
Affiliation:
Department of Mathematics, University of Sarajevo, 71000 Sarajevo, Yugoslavia
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Abstract

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Strong convergence has been investigated in summability theory and Fourier analysis. This paper extends strong convergence to a topological property of sequence spaces E. The more general property of strong boundedness is also defined and examined. One of the main results shows that for an FK-space E which contains all finite sequences, strong convergence is equivalent to the invariance property E = ℓ ν0. E with respect to coordinatewise multiplication by sequences in the space ℓν0 defined in the paper. Similarly, strong boundedness is equivalent to another invariance E = ℓν.E. The results of the paper are applied to summability fields and spaces of Fourier series.

Keywords

Type
Research Article
Copyright
Copyright © Canadian Mathematical Society 1991

References

1. Borwein, D., On strong and absolute summability, Proc. Glasgow Math. Assoc. 4 (1960), 122139.Google Scholar
2. Buntinas, M., Convergent and bounded Cesàro sections in FK-spaces, Math. Z. 121 (1971), 191200.Google Scholar
3. Buntinas, M., On Toeplitz sections in sequence spaces, Math. Proc. Cambridge Philos. Soc. 78 (1975), 451460.Google Scholar
4. Buntinas, M., Strong summability in Fréchet spaces with applications to Fourier series, J. Approximation Theory 67 (1991), to appear.Google Scholar
5. Buntinas, M. and Tanović-Miller, N., A£so/Mte boundedness and absolute convergence in sequences spaces, Proc. Amer. Math. Soc. 111 (1991), 967979.Google Scholar
6. Edwards, R.E., Fourier Series: A Modern Introduction, vols. 1 and 2, Holt, Rinehart and Winston, 1967.Google Scholar
7. Garling, D.J.H., On topological sequence spaces, Proc. Cambridge Philos. Soc. 63 (1967), 9971019.Google Scholar
8. Hyslop, J.M., Note on the strong summability of series, Proc. Glasgow Math. Assoc. 1(1951/53), 1620.Google Scholar
9. Kuttner, B. and Maddox, I.J., On strong convergence factors, Quart. J. Math. Oxford (2)16 (1965), 165182.Google Scholar
10. Kuttner, B. and Thorpe, B., Strong convergence, J. fur die reine und angewandte Math. 311/ 312 (1979), 4256.Google Scholar
11. Sember, J.J., On unconditional section boundedness in sequence spaces, Rocky Mountain J. Math. 7 (1977), 699706.Google Scholar
12. Sember, J. and Raphael, M., The unrestricted section properties of sequences, Can. J. Math. 31 (1979), 331— 336.Google Scholar
13. Szalay, I. and Tanović-Miller, N., On Banach spaces of absolutely and strongly convergent Fourier series, Acta Math. Hung. 55 (1990), 149160.Google Scholar
14. Szalay, I. and Tanović-Miller, N., On Banach spaces of absolutely and strongly convergent Fourier series, II, Acta Math. Hung., to appear.Google Scholar
15. Tanović-Miller, N., On strong convergence oftrigonometric and Fourier series, Acta Math. Hung. 42 (1983), 3543.Google Scholar
16. Tanović-Miller, N., Strongly convergent trigonometric series as Fourier series, Acta Math. Hung. 47 (1986), 127135.Google Scholar
17. Tanović-Miller, N., On Banach spaces of strongly convergent trigonometric series, J. Math. Anal, and Appl. 46(1990), 110127.Google Scholar
18. Zeller, K., Allgemeine Eigenschaften von Limitierungsverfahren, Math. Z. 53 (1951), 463487.Google Scholar
19. Zygmund, A., Trigonometric Series. Cambridge University Press, 1968.Google Scholar