Fourier series

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In mathematics, the Fourier series, named after Joseph Fourier (1768—1830), of a complex-valued periodic function f of a real variable ξ, of period P:

f(\xi +P)=f(\xi )\ ,

is equivalent to an infinite series

f(\xi )=\sum _{n=-\infty }^{\infty }c_{n}e^{2\pi in\xi /P}

defined by

c_{n}={\frac {1}{P}}\int _{0}^{P}f(\xi )\exp \left({\frac {-2\pi inx}{P}}\right)\,d\xi \ .

In what sense it may be said that this series converges to f(x) is a somewhat delicate question.^[1]^[2] However, physicists being less delicate than mathematicians in these matters, simply write

f(\xi )=\sum _{n=-\infty }^{\infty }c_{n}e^{2\pi in\xi /P}\ ,

and usually do not worry too much about the conditions to be imposed on the arbitrary function f(ξ) of period P in order that this expansion converge to the function.

References

↑ G. H. Hardy, Werner Rogosinski (1999). “Chapter IV: Convergence of Fourier series”, Fourier Series, Reprint of Cambridge University Press 1956 ed. Courier Dover Publications, pp. 37 ff. ISBN 0486406814.
↑ For an historical account, see Hans Niels Jahnke (2003). “§6.5 Convergence of Fourier series”, A History of Analysis. American Mathematical Society, pp. 178 ff. ISBN 0821826239.

[Hardy-1] G. H. Hardy, Werner Rogosinski (1999). “Chapter IV: Convergence of Fourier series”, Fourier Series, Reprint of Cambridge University Press 1956 ed. Courier Dover Publications, pp. 37 ff. ISBN 0486406814.

[Jahnke-2] For an historical account, see Hans Niels Jahnke (2003). “§6.5 Convergence of Fourier series”, A History of Analysis. American Mathematical Society, pp. 178 ff. ISBN 0821826239.

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Fourier series

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