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Dirichlet–Jordan test

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In mathematics, the Dirichlet–Jordan test gives sufficient conditions for a real-valued, periodic function f to be equal to the sum of its Fourier series at a point of continuity. Moreover, the behavior of the Fourier series at points of discontinuity is determined as well (it is the midpoint of the values of the discontinuity). It is one of many conditions for the convergence of Fourier series.

The original test was established by Peter Gustav Lejeune Dirichlet in 1829,[1] for piecewise monotone functions (functions with a finite number of sections per period each of which is monotonic). It was extended in the late 19th century by Camille Jordan to functions of bounded variation in each period (any function of bounded variation is the difference of two monotonically increasing functions).[2][3][4]

Dirichlet–Jordan test for Fourier series

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The Dirichlet–Jordan test states[5] that if a periodic function is of bounded variation on a period, then the Fourier series converges, as , at each point of the domain to In particular, if is continuous at , then the Fourier series converges to . Moreover, if is continuous everywhere, then the convergence is uniform.

Stated in terms of a periodic function of period 2π, the Fourier series coefficients are defined as and the partial sums of the Fourier series are

The analogous statement holds irrespective of what the period of f is, or which version of the Fourier series is chosen.

There is also a pointwise version of the test:[6] if is a periodic function in , and is of bounded variation in a neighborhood of , then the Fourier series at converges to the limit as above

Jordan test for Fourier integrals

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For the Fourier transform on the real line, there is a version of the test as well.[7] Suppose that is in and of bounded variation in a neighborhood of the point . Then If is continuous in an open interval, then the integral on the left-hand side converges uniformly in the interval, and the limit on the right-hand side is .

This version of the test (although not satisfying modern demands for rigor) is historically prior to Dirichlet, being due to Joseph Fourier.[2]

Dirichlet conditions in signal processing

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In signal processing,[8] the test is often retained in the original form due to Dirichlet: a piecewise monotone bounded periodic function (having a finite number of monotonic intervals per period) has a convergent Fourier series whose value at each point is the arithmetic mean of the left and right limits of the function. The condition of piecewise monotonicity stipulates having only finitely many local extrema per period, i.e., that the function changes its variation only finitely many times. This may be called a function of "finite variation", as opposed to bounded variation.[2][9] Finite variation implies bounded variation, but the reverse is not true. (Dirichlet required in addition that the function have only finitely many discontinuities, but this constraint is unnecessarily stringent.[10]) Any signal that can be physically produced in a laboratory satisfies these conditions.[11]

As in the pointwise case of the Jordan test, the condition of boundedness can be relaxed if the function is assumed to be absolutely integrable (i.e., ) over a period, provided it satisfies the other conditions of the test in a neighborhood of the point where the limit is taken.[12]

See also

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References

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  1. ^ Dirichlet (1829), "Sur la convergence des series trigonometriques qui servent à represénter une fonction arbitraire entre des limites donnees", J. Reine Angew. Math., 4: 157–169
  2. ^ a b c Jaak Peetre (2000), On Fourier's discovery of Fourier series and Fourier integrals
  3. ^ C. Jordan, Cours d'analyse de l'Ecole Polytechnique, t.2, calcul integral, Gauthier-Villars, Paris, 1894
  4. ^ Georges A. Lion (1986), "A Simple Proof of the Dirichlet-Jordan Convergence Test", The American Mathematical Monthly, 93 (4)
  5. ^ Antoni Zygmund (1952), Trigonometric series, Cambridge University Press, p. 57
  6. ^ R. E. Edwards (1967), Fourier series: a modern introduction, Springer, p. 156.
  7. ^ E. C. Titchmarsh (1948), Introduction to the theory of Fourier integrals, Oxford Clarendon Press, p. 13.
  8. ^ Alan V. Oppenheim; Alan S. Willsky; Syed Hamish Nawab (1997). Signals & Systems. Prentice Hall. p. 198. ISBN 9780136511755.
  9. ^ Vladimir Dobrushkin, Mathematica Tutorial for the Second Course. Part V: Convergence of Fourier Series: " A function that satisfies the Dirichlet conditions is also called piecewise monotone."
  10. ^ Cornelius Lanczos (2016), Discourse on Fourier series, SIAM, p. 46.
  11. ^ B P Lathi (2000), Signal processing and linear systems, Oxford
  12. ^ Cornelius Lanczos (2016), Discourse on Fourier series, SIAM, p. 48.
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