Fourier series

(Redirected from Fourier's theorem)

A Fourier series (/ˈfʊri, -iər/[1]) is an expansion of a periodic function into a sum of trigonometric functions. The Fourier series is an example of a trigonometric series, but not all trigonometric series are Fourier series.[2] By expressing a function as a sum of sines and cosines, many problems involving the function become easier to analyze because trigonometric functions are well understood. For example, Fourier series were first used by Joseph Fourier to find solutions to the heat equation. This application is possible because the derivatives of trigonometric functions fall into simple patterns. Fourier series cannot be used to approximate arbitrary functions, because most functions have infinitely many terms in their Fourier series, and the series do not always converge. Well-behaved functions, for example smooth functions, have Fourier series that converge to the original function. The coefficients of the Fourier series are determined by integrals of the function multiplied by trigonometric functions, described in Common forms of the Fourier series below.

The study of the convergence of Fourier series focus on the behaviors of the partial sums, which means studying the behavior of the sum as more and more terms from the series are summed. The figures below illustrate some partial Fourier series results for the components of a square wave.

Fourier series are closely related to the Fourier transform, a more general tool that can even find the frequency information for functions that are not periodic. Periodic functions can be identified with functions on a circle; for this reason Fourier series are the subject of Fourier analysis on a circle, usually denoted as or . The Fourier transform is also part of Fourier analysis, but is defined for functions on .

Since Fourier's time, many different approaches to defining and understanding the concept of Fourier series have been discovered, all of which are consistent with one another, but each of which emphasizes different aspects of the topic. Some of the more powerful and elegant approaches are based on mathematical ideas and tools that were not available in Fourier's time. Fourier originally defined the Fourier series for real-valued functions of real arguments, and used the sine and cosine functions in the decomposition. Many other Fourier-related transforms have since been defined, extending his initial idea to many applications and birthing an area of mathematics called Fourier analysis.

Common forms of the Fourier series

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A Fourier series is a continuous, periodic function created by a summation of harmonically related sinusoidal functions. It has several different, but equivalent, forms, shown here as partial sums. But in theory   The subscripted symbols, called coefficients, and the period,   determine the function   as follows:

 
Fig 1. The top graph shows a non-periodic function s(x) in blue defined only over the red interval from 0 to P. The function can be analyzed over this interval to produce the Fourier series in the bottom graph. The Fourier series is always a periodic function, even if original function s(x) isn't.
Fourier series, amplitude-phase form
      (Eq.1)


Fourier series, sine-cosine form
      (Eq.2)


Fourier series, exponential form
      (Eq.3)

The harmonics are indexed by an integer,   which is also the number of cycles the corresponding sinusoids make in interval  . Therefore, the sinusoids have:

  • a wavelength equal to   in the same units as  .
  • a frequency equal to   in the reciprocal units of  .

Clearly these series can represent functions that are just a sum of one or more of the harmonic frequencies. The remarkable thing is that it can also represent the intermediate frequencies and/or non-sinusoidal functions because of the infinite number of terms. The amplitude-phase form is particularly useful for its insight into the rationale for the series coefficients. (see § Derivation) The exponential form is most easily generalized for complex-valued functions. (see § Complex-valued functions)

The equivalence of these forms requires certain relationships among the coefficients. For instance, the trigonometric identity:

Equivalence of polar and rectangular forms
      (Eq.4)

means that:

     

(Eq.4.1)

Therefore   and   are the rectangular coordinates of a vector with polar coordinates   and  

The coefficients can be given/assumed, such as a music synthesizer or time samples of a waveform. In the latter case, the exponential form of Fourier series synthesizes a discrete-time Fourier transform where variable   represents frequency instead of time.

But typically the coefficients are determined by frequency/harmonic analysis of a given real-valued function   and   represents time:

Fourier series analysis
      (Eq.5)

The objective is for   to converge to   at most or all values of   in an interval of length   For the well-behaved functions typical of physical processes, equality is customarily assumed, and the Dirichlet conditions provide sufficient conditions.

The notation  represents integration over the chosen interval. Typical choices are   and  . Some authors define   because it simplifies the arguments of the sinusoid functions, at the expense of generality. And some authors assume that   is also  -periodic, in which case   approximates the entire function. The   scaling factor is explained by taking a simple case:   Only the   term of Eq.2 is needed for convergence, with   and    Accordingly Eq.5 provides:

        as required.

Exponential form coefficients

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Another applicable identity is Euler's formula:

 

(Note: the ∗ denotes complex conjugation.)

Substituting this into Eq.1 and comparison with Eq.3 ultimately reveals:

Exponential form coefficients

     

(Eq.6)

Conversely:

Inverse relationships

 

Substituting Eq.5 into Eq.6 also reveals:[3]

Fourier series analysis

  (all integers)    

(Eq.7)

Complex-valued functions

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Eq.7 and Eq.3 also apply when   is a complex-valued function.[A] This follows by expressing   and   as separate real-valued Fourier series, and  

Derivation

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The coefficients   and   can be understood and derived in terms of the cross-correlation between   and a sinusoid at frequency  . For a general frequency   and an analysis interval   the cross-correlation function:

 
Fig 2. The blue curve is the cross-correlation of a square wave and a cosine function, as the phase lag of the cosine varies over one cycle. The amplitude and phase lag at the maximum value are the polar coordinates of one harmonic in the Fourier series expansion of the square wave. The corresponding rectangular coordinates can be determined by evaluating the cross-correlation at just two phase lags separated by 90º.
Derivation of Eq.1
      (Eq.8)

is essentially a matched filter, with template  . The maximum of   is a measure of the amplitude   of frequency   in the function  , and the value of   at the maximum determines the phase   of that frequency. Figure 2 is an example, where   is a square wave (not shown), and frequency   is the   harmonic. It is also an example of deriving the maximum from just two samples, instead of searching the entire function. Combining Eq.8 with Eq.4 gives:

 

The derivative of   is zero at the phase of maximum correlation.

 

Therefore, computing   and   according to Eq.5 creates the component's phase   of maximum correlation. And the component's amplitude is:

 

Other common notations

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The notation   is inadequate for discussing the Fourier coefficients of several different functions. Therefore, it is customarily replaced by a modified form of the function (  in this case), such as   or  , and functional notation often replaces subscripting:

 

In engineering, particularly when the variable   represents time, the coefficient sequence is called a frequency domain representation. Square brackets are often used to emphasize that the domain of this function is a discrete set of frequencies.

Another commonly used frequency domain representation uses the Fourier series coefficients to modulate a Dirac comb:

 

where   represents a continuous frequency domain. When variable   has units of seconds,   has units of hertz. The "teeth" of the comb are spaced at multiples (i.e. harmonics) of  , which is called the fundamental frequency.   can be recovered from this representation by an inverse Fourier transform:

 

The constructed function   is therefore commonly referred to as a Fourier transform, even though the Fourier integral of a periodic function is not convergent at the harmonic frequencies.[B]

Analysis example

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Plot of the sawtooth wave, a periodic continuation of the linear function   on the interval  
 
Animated plot of the first five successive partial Fourier series

Consider a sawtooth function:

 
 

In this case, the Fourier coefficients are given by

 

It can be shown that the Fourier series converges to   at every point   where   is differentiable, and therefore:

      (Eq.9)

When  , the Fourier series converges to 0, which is the half-sum of the left- and right-limit of s at  . This is a particular instance of the Dirichlet theorem for Fourier series.

This example leads to a solution of the Basel problem.

Convergence

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A proof that a Fourier series is a valid representation of any periodic function (that satisfies the Dirichlet conditions) is overviewed in § Fourier theorem proving convergence of Fourier series.

In engineering applications, the Fourier series is generally assumed to converge except at jump discontinuities since the functions encountered in engineering are better-behaved than functions encountered in other disciplines. In particular, if   is continuous and the derivative of   (which may not exist everywhere) is square integrable, then the Fourier series of   converges absolutely and uniformly to  .[4] If a function is square-integrable on the interval  , then the Fourier series converges to the function at almost everywhere. It is possible to define Fourier coefficients for more general functions or distributions, in which case point wise convergence often fails, and convergence in norm or weak convergence is usually studied.

History

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The Fourier series is named in honor of Jean-Baptiste Joseph Fourier (1768–1830), who made important contributions to the study of trigonometric series, after preliminary investigations by Leonhard Euler, Jean le Rond d'Alembert, and Daniel Bernoulli.[C] Fourier introduced the series for the purpose of solving the heat equation in a metal plate, publishing his initial results in his 1807 Mémoire sur la propagation de la chaleur dans les corps solides (Treatise on the propagation of heat in solid bodies), and publishing his Théorie analytique de la chaleur (Analytical theory of heat) in 1822. The Mémoire introduced Fourier analysis, specifically Fourier series. Through Fourier's research the fact was established that an arbitrary (at first, continuous[5] and later generalized to any piecewise-smooth[6]) function can be represented by a trigonometric series. The first announcement of this great discovery was made by Fourier in 1807, before the French Academy.[7] Early ideas of decomposing a periodic function into the sum of simple oscillating functions date back to the 3rd century BC, when ancient astronomers proposed an empiric model of planetary motions, based on deferents and epicycles.

The heat equation is a partial differential equation. Prior to Fourier's work, no solution to the heat equation was known in the general case, although particular solutions were known if the heat source behaved in a simple way, in particular, if the heat source was a sine or cosine wave. These simple solutions are now sometimes called eigensolutions. Fourier's idea was to model a complicated heat source as a superposition (or linear combination) of simple sine and cosine waves, and to write the solution as a superposition of the corresponding eigensolutions. This superposition or linear combination is called the Fourier series.

From a modern point of view, Fourier's results are somewhat informal, due to the lack of a precise notion of function and integral in the early nineteenth century. Later, Peter Gustav Lejeune Dirichlet[8] and Bernhard Riemann[9][10][11] expressed Fourier's results with greater precision and formality.

Although the original motivation was to solve the heat equation, it later became obvious that the same techniques could be applied to a wide array of mathematical and physical problems, and especially those involving linear differential equations with constant coefficients, for which the eigensolutions are sinusoids. The Fourier series has many such applications in electrical engineering, vibration analysis, acoustics, optics, signal processing, image processing, quantum mechanics, econometrics,[12] shell theory,[13] etc.

Beginnings

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Joseph Fourier wrote:[dubiousdiscuss]

 

Multiplying both sides by  , and then integrating from   to   yields:

 

This immediately gives any coefficient ak of the trigonometrical series for φ(y) for any function which has such an expansion. It works because if φ has such an expansion, then (under suitable convergence assumptions) the integral   can be carried out term-by-term. But all terms involving   for jk vanish when integrated from −1 to 1, leaving only the   term.

In these few lines, which are close to the modern formalism used in Fourier series, Fourier revolutionized both mathematics and physics. Although similar trigonometric series were previously used by Euler, d'Alembert, Daniel Bernoulli and Gauss, Fourier believed that such trigonometric series could represent any arbitrary function. In what sense that is actually true is a somewhat subtle issue and the attempts over many years to clarify this idea have led to important discoveries in the theories of convergence, function spaces, and harmonic analysis.

When Fourier submitted a later competition essay in 1811, the committee (which included Lagrange, Laplace, Malus and Legendre, among others) concluded: ...the manner in which the author arrives at these equations is not exempt of difficulties and...his analysis to integrate them still leaves something to be desired on the score of generality and even rigour.[citation needed]

Fourier's motivation

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Heat distribution in a metal plate, using Fourier's method

The Fourier series expansion of the sawtooth function (above) looks more complicated than the simple formula  , so it is not immediately apparent why one would need the Fourier series. While there are many applications, Fourier's motivation was in solving the heat equation. For example, consider a metal plate in the shape of a square whose sides measure   meters, with coordinates  . If there is no heat source within the plate, and if three of the four sides are held at 0 degrees Celsius, while the fourth side, given by  , is maintained at the temperature gradient   degrees Celsius, for   in  , then one can show that the stationary heat distribution (or the heat distribution after a long period of time has elapsed) is given by

 

Here, sinh is the hyperbolic sine function. This solution of the heat equation is obtained by multiplying each term of Eq.9 by  . While our example function   seems to have a needlessly complicated Fourier series, the heat distribution   is nontrivial. The function   cannot be written as a closed-form expression. This method of solving the heat problem was made possible by Fourier's work.

Other applications

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Another application is to solve the Basel problem by using Parseval's theorem. The example generalizes and one may compute ζ(2n), for any positive integer n.

Table of common Fourier series

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Some common pairs of periodic functions and their Fourier series coefficients are shown in the table below.

  •   designates a periodic function with period  .
  •   designate the Fourier series coefficients (sine-cosine form) of the periodic function  .
Time domain
 
Plot Frequency domain (sine-cosine form)
 
Remarks Reference
 
 
  Full-wave rectified sine [15]: p. 193 
 
 
  Half-wave rectified sine [15]: p. 193 
 
 
   
 
 
  [15]: p. 192 
 
 
  [15]: p. 192 
 
 
  [15]: p. 193 

Table of basic properties

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This table shows some mathematical operations in the time domain and the corresponding effect in the Fourier series coefficients. Notation:

  • Complex conjugation is denoted by an asterisk.
  •   designate  -periodic functions or functions defined only for  
  •   designate the Fourier series coefficients (exponential form) of   and  
Property Time domain Frequency domain (exponential form) Remarks Reference
Linearity      
Time reversal / Frequency reversal     [16]: p. 610 
Time conjugation     [16]: p. 610 
Time reversal & conjugation    
Real part in time    
Imaginary part in time    
Real part in frequency    
Imaginary part in frequency    
Shift in time / Modulation in frequency       [16]: p.610 
Shift in frequency / Modulation in time       [16]: p. 610 

Symmetry properties

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When the real and imaginary parts of a complex function are decomposed into their even and odd parts, there are four components, denoted below by the subscripts RE, RO, IE, and IO. And there is a one-to-one mapping between the four components of a complex time function and the four components of its complex frequency transform:[17]

 

From this, various relationships are apparent, for example:

  • The transform of a real-valued function   is the conjugate symmetric function   Conversely, a conjugate symmetric transform implies a real-valued time-domain.
  • The transform of an imaginary-valued function   is the conjugate antisymmetric function   and the converse is true.
  • The transform of a conjugate symmetric function   is the real-valued function   and the converse is true.
  • The transform of a conjugate antisymmetric function   is the imaginary-valued function   and the converse is true.

Other properties

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Riemann–Lebesgue lemma

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If   is integrable,  ,   and   This result is known as the Riemann–Lebesgue lemma.

Parseval's theorem

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If   belongs to   (periodic over an interval of length  ) then:  

Plancherel's theorem

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If   are coefficients and   then there is a unique function   such that   for every  .

Convolution theorems

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Given  -periodic functions,   and   with Fourier series coefficients   and    

  • The pointwise product:   is also  -periodic, and its Fourier series coefficients are given by the discrete convolution of the   and   sequences:  
  • The periodic convolution:   is also  -periodic, with Fourier series coefficients:  
  • A doubly infinite sequence   in   is the sequence of Fourier coefficients of a function in   if and only if it is a convolution of two sequences in  . See [18]

Derivative property

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We say that   belongs to   if   is a 2π-periodic function on   which is   times differentiable, and its   derivative is continuous.

  • If  , then the Fourier coefficients   of the derivative   can be expressed in terms of the Fourier coefficients   of the function  , via the formula  .
  • If  , then  . In particular, since for a fixed   we have   as  , it follows that   tends to zero, which means that the Fourier coefficients converge to zero faster than the kth power of n for any  .

Compact groups

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One of the interesting properties of the Fourier transform which we have mentioned, is that it carries convolutions to pointwise products. If that is the property which we seek to preserve, one can produce Fourier series on any compact group. Typical examples include those classical groups that are compact. This generalizes the Fourier transform to all spaces of the form L2(G), where G is a compact group, in such a way that the Fourier transform carries convolutions to pointwise products. The Fourier series exists and converges in similar ways to the [−π,π] case.

An alternative extension to compact groups is the Peter–Weyl theorem, which proves results about representations of compact groups analogous to those about finite groups.

 
The atomic orbitals of chemistry are partially described by spherical harmonics, which can be used to produce Fourier series on the sphere.

Riemannian manifolds

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If the domain is not a group, then there is no intrinsically defined convolution. However, if   is a compact Riemannian manifold, it has a Laplace–Beltrami operator. The Laplace–Beltrami operator is the differential operator that corresponds to Laplace operator for the Riemannian manifold  . Then, by analogy, one can consider heat equations on  . Since Fourier arrived at his basis by attempting to solve the heat equation, the natural generalization is to use the eigensolutions of the Laplace–Beltrami operator as a basis. This generalizes Fourier series to spaces of the type  , where   is a Riemannian manifold. The Fourier series converges in ways similar to the   case. A typical example is to take   to be the sphere with the usual metric, in which case the Fourier basis consists of spherical harmonics.

Locally compact Abelian groups

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The generalization to compact groups discussed above does not generalize to noncompact, nonabelian groups. However, there is a straightforward generalization to Locally Compact Abelian (LCA) groups.

This generalizes the Fourier transform to   or  , where   is an LCA group. If   is compact, one also obtains a Fourier series, which converges similarly to the   case, but if   is noncompact, one obtains instead a Fourier integral. This generalization yields the usual Fourier transform when the underlying locally compact Abelian group is  .

Extensions

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Fourier series on a square

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We can also define the Fourier series for functions of two variables   and   in the square  :  

Aside from being useful for solving partial differential equations such as the heat equation, one notable application of Fourier series on the square is in image compression. In particular, the JPEG image compression standard uses the two-dimensional discrete cosine transform, a discrete form of the Fourier cosine transform, which uses only cosine as the basis function.

For two-dimensional arrays with a staggered appearance, half of the Fourier series coefficients disappear, due to additional symmetry.[19]

Fourier series of Bravais-lattice-periodic-function

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A three-dimensional Bravais lattice is defined as the set of vectors of the form:   where   are integers and   are three linearly independent vectors. Assuming we have some function,  , such that it obeys the condition of periodicity for any Bravais lattice vector  ,  , we could make a Fourier series of it. This kind of function can be, for example, the effective potential that one electron "feels" inside a periodic crystal. It is useful to make the Fourier series of the potential when applying Bloch's theorem. First, we may write any arbitrary position vector   in the coordinate-system of the lattice:   where   meaning that   is defined to be the magnitude of  , so   is the unit vector directed along  .

Thus we can define a new function,  

This new function,  , is now a function of three-variables, each of which has periodicity  ,  , and   respectively:  

This enables us to build up a set of Fourier coefficients, each being indexed by three independent integers  . In what follows, we use function notation to denote these coefficients, where previously we used subscripts. If we write a series for   on the interval   for  , we can define the following:  

And then we can write:  

Further defining:  

We can write   once again as:  

Finally applying the same for the third coordinate, we define:  

We write   as:  

Re-arranging:  

Now, every reciprocal lattice vector can be written (but does not mean that it is the only way of writing) as  , where   are integers and   are reciprocal lattice vectors to satisfy   (  for  , and   for  ). Then for any arbitrary reciprocal lattice vector   and arbitrary position vector   in the original Bravais lattice space, their scalar product is:  

So it is clear that in our expansion of  , the sum is actually over reciprocal lattice vectors:  

where  

Assuming   we can solve this system of three linear equations for  ,  , and   in terms of  ,   and   in order to calculate the volume element in the original rectangular coordinate system. Once we have  ,  , and   in terms of  ,   and  , we can calculate the Jacobian determinant:   which after some calculation and applying some non-trivial cross-product identities can be shown to be equal to:  

(it may be advantageous for the sake of simplifying calculations, to work in such a rectangular coordinate system, in which it just so happens that   is parallel to the x axis,   lies in the xy-plane, and   has components of all three axes). The denominator is exactly the volume of the primitive unit cell which is enclosed by the three primitive-vectors  ,   and  . In particular, we now know that  

We can write now   as an integral with the traditional coordinate system over the volume of the primitive cell, instead of with the  ,   and   variables:   writing   for the volume element  ; and where   is the primitive unit cell, thus,   is the volume of the primitive unit cell.

Hilbert space interpretation

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In the language of Hilbert spaces, the set of functions   is an orthonormal basis for the space   of square-integrable functions on  . This space is actually a Hilbert space with an inner product given for any two elements   and   by:

  where   is the complex conjugate of  

The basic Fourier series result for Hilbert spaces can be written as

 
 
Sines and cosines form an orthogonal set, as illustrated above. The integral of sine, cosine and their product is zero (green and red areas are equal, and cancel out) when  ,   or the functions are different, and π only if   and   are equal, and the function used is the same. They would form an orthonormal set, if the integral equaled 1 (that is, each function would need to be scaled by  ).

This corresponds exactly to the complex exponential formulation given above. The version with sines and cosines is also justified with the Hilbert space interpretation. Indeed, the sines and cosines form an orthogonal set:     (where δmn is the Kronecker delta), and   furthermore, the sines and cosines are orthogonal to the constant function  . An orthonormal basis for   consisting of real functions is formed by the functions   and  ,   with n= 1,2,.... The density of their span is a consequence of the Stone–Weierstrass theorem, but follows also from the properties of classical kernels like the Fejér kernel.

Fourier theorem proving convergence of Fourier series

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These theorems, and informal variations of them that don't specify the convergence conditions, are sometimes referred to generically as Fourier's theorem or the Fourier theorem.[20][21][22][23]

The earlier Eq.3:

 

is a trigonometric polynomial of degree   that can be generally expressed as:

 

Least squares property

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Parseval's theorem implies that:

Theorem — The trigonometric polynomial   is the unique best trigonometric polynomial of degree   approximating  , in the sense that, for any trigonometric polynomial   of degree  , we have:   where the Hilbert space norm is defined as:  

Convergence theorems

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Because of the least squares property, and because of the completeness of the Fourier basis, we obtain an elementary convergence result.

Theorem — If   belongs to   (an interval of length  ), then   converges to   in  , that is,    converges to 0 as  .

We have already mentioned that if   is continuously differentiable, then   is the   Fourier coefficient of the derivative  . Since the derivative is continuous, and therefore bounded, it is square-integrable and its Fourier coefficients are square-summable. Then, by the Cauchy–Schwarz inequality,

 

This means that   is absolutely summable. The sum of this series is a continuous function, equal to  , since the Fourier series converges in   to  :

Theorem — If  , then   converges to   uniformly (and hence also pointwise.)

This result can be proven easily if   is further assumed to be  , since in that case   tends to zero as  . More generally, the Fourier series is absolutely summable, thus converges uniformly to  , provided that   satisfies a Hölder condition of order  . In the absolutely summable case, the inequality:

 

proves uniform convergence.

Many other results concerning the convergence of Fourier series are known, ranging from the moderately simple result that the series converges at   if   is differentiable at  , to Lennart Carleson's much more sophisticated result that the Fourier series of an   function actually converges almost everywhere.

Divergence

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Since Fourier series have such good convergence properties, many are often surprised by some of the negative results. For example, the Fourier series of a continuous T-periodic function need not converge pointwise. The uniform boundedness principle yields a simple non-constructive proof of this fact.

In 1922, Andrey Kolmogorov published an article titled Une série de Fourier-Lebesgue divergente presque partout in which he gave an example of a Lebesgue-integrable function whose Fourier series diverges almost everywhere. He later constructed an example of an integrable function whose Fourier series diverges everywhere.[24]

It is possible to give explicit examples of a continuous function whose Fourier series diverges at 0: for instance, the even and 2π-periodic function f defined for all x in [0,π] by[25]

 

Because the function is even the Fourier series contains only cosines:

 

The coefficients are:

 

As m increases, the coefficients will be positive and increasing until they reach a value of about   at   for some n and then become negative (starting with a value around  ) and getting smaller, before starting a new such wave. At   the Fourier series is simply the running sum of   and this builds up to around

 

in the nth wave before returning to around zero, showing that the series does not converge at zero but reaches higher and higher peaks. Note that though the function is continuous, it is not differentiable.

See also

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Notes

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  1. ^ But  , in general.
  2. ^ Since the integral defining the Fourier transform of a periodic function is not convergent, it is necessary to view the periodic function and its transform as distributions. In this sense   is a Dirac delta function, which is an example of a distribution.
  3. ^ These three did some important early work on the wave equation, especially D'Alembert. Euler's work in this area was mostly comtemporaneous/ in collaboration with Bernoulli, although the latter made some independent contributions to the theory of waves and vibrations. (See Fetter & Walecka 2003, pp. 209–210).
  4. ^ These words are not strictly Fourier's. Whilst the cited article does list the author as Fourier, a footnote indicates that the article was actually written by Poisson (that it was not written by Fourier is also clear from the consistent use of the third person to refer to him) and that it is, "for reasons of historical interest", presented as though it were Fourier's original memoire.

References

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  1. ^ "Fourier". Dictionary.com Unabridged (Online). n.d.
  2. ^ Zygmund, A. (2002). Trigonometric Series (3rd ed.). Cambridge, UK: Cambridge University Press. ISBN 0-521-89053-5.
  3. ^ Pinkus, Allan; Zafrany, Samy (1997). Fourier Series and Integral Transforms (1st ed.). Cambridge, UK: Cambridge University Press. pp. 42–44. ISBN 0-521-59771-4.
  4. ^ Tolstov, Georgi P. (1976). Fourier Series. Courier-Dover. ISBN 0-486-63317-9.
  5. ^ Stillwell, John (2013). "Logic and the philosophy of mathematics in the nineteenth century". In Ten, C. L. (ed.). Routledge History of Philosophy. Vol. VII: The Nineteenth Century. Routledge. p. 204. ISBN 978-1-134-92880-4.
  6. ^ Fasshauer, Greg (2015). "Fourier Series and Boundary Value Problems" (PDF). Math 461 Course Notes, Ch 3. Department of Applied Mathematics, Illinois Institute of Technology. Retrieved 6 November 2020.
  7. ^ Cajori, Florian (1893). A History of Mathematics. Macmillan. p. 283.
  8. ^ Lejeune-Dirichlet, Peter Gustav (1829). "Sur la convergence des séries trigonométriques qui servent à représenter une fonction arbitraire entre des limites données" [On the convergence of trigonometric series which serve to represent an arbitrary function between two given limits]. Journal für die reine und angewandte Mathematik (in French). 4: 157–169. arXiv:0806.1294.
  9. ^ "Ueber die Darstellbarkeit einer Function durch eine trigonometrische Reihe" [About the representability of a function by a trigonometric series]. Habilitationsschrift, Göttingen; 1854. Abhandlungen der Königlichen Gesellschaft der Wissenschaften zu Göttingen, vol. 13, 1867. Published posthumously for Riemann by Richard Dedekind (in German). Archived from the original on 20 May 2008. Retrieved 19 May 2008.
  10. ^ Mascre, D.; Riemann, Bernhard (1867), "Posthumous Thesis on the Representation of Functions by Trigonometric Series", in Grattan-Guinness, Ivor (ed.), Landmark Writings in Western Mathematics 1640–1940, Elsevier (published 2005), p. 49, ISBN 9780080457444
  11. ^ Remmert, Reinhold (1991). Theory of Complex Functions: Readings in Mathematics. Springer. p. 29. ISBN 9780387971957.
  12. ^ Nerlove, Marc; Grether, David M.; Carvalho, Jose L. (1995). Analysis of Economic Time Series. Economic Theory, Econometrics, and Mathematical Economics. Elsevier. ISBN 0-12-515751-7.
  13. ^ Wilhelm Flügge, Stresses in Shells (1973) 2nd edition. ISBN 978-3-642-88291-3. Originally published in German as Statik und Dynamik der Schalen (1937).
  14. ^ Fourier, Jean-Baptiste-Joseph (1888). Gaston Darboux (ed.). Oeuvres de Fourier [The Works of Fourier] (in French). Paris: Gauthier-Villars et Fils. pp. 218–219 – via Gallica.
  15. ^ a b c d e Papula, Lothar (2009). Mathematische Formelsammlung: für Ingenieure und Naturwissenschaftler [Mathematical Functions for Engineers and Physicists] (in German). Vieweg+Teubner Verlag. ISBN 978-3834807571.
  16. ^ a b c d Shmaliy, Y.S. (2007). Continuous-Time Signals. Springer. ISBN 978-1402062711.
  17. ^ Proakis, John G.; Manolakis, Dimitris G. (1996). Digital Signal Processing: Principles, Algorithms, and Applications (3rd ed.). Prentice Hall. p. 291. ISBN 978-0-13-373762-2.
  18. ^ "Characterizations of a linear subspace associated with Fourier series". MathOverflow. 2010-11-19. Retrieved 2014-08-08.
  19. ^ Vanishing of Half the Fourier Coefficients in Staggered Arrays
  20. ^ Siebert, William McC. (1985). Circuits, signals, and systems. MIT Press. p. 402. ISBN 978-0-262-19229-3.
  21. ^ Marton, L.; Marton, Claire (1990). Advances in Electronics and Electron Physics. Academic Press. p. 369. ISBN 978-0-12-014650-5.
  22. ^ Kuzmany, Hans (1998). Solid-state spectroscopy. Springer. p. 14. ISBN 978-3-540-63913-8.
  23. ^ Pribram, Karl H.; Yasue, Kunio; Jibu, Mari (1991). Brain and perception. Lawrence Erlbaum Associates. p. 26. ISBN 978-0-89859-995-4.
  24. ^ Katznelson, Yitzhak (1976). An introduction to Harmonic Analysis (2nd corrected ed.). New York, NY: Dover Publications, Inc. ISBN 0-486-63331-4.
  25. ^ Gourdon, Xavier (2009). Les maths en tête. Analyse (2ème édition) (in French). Ellipses. p. 264. ISBN 978-2729837594.

Further reading

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  • William E. Boyce; Richard C. DiPrima (2005). Elementary Differential Equations and Boundary Value Problems (8th ed.). New Jersey: John Wiley & Sons, Inc. ISBN 0-471-43338-1.
  • Joseph Fourier, translated by Alexander Freeman (2003). The Analytical Theory of Heat. Dover Publications. ISBN 0-486-49531-0. 2003 unabridged republication of the 1878 English translation by Alexander Freeman of Fourier's work Théorie Analytique de la Chaleur, originally published in 1822.
  • Enrique A. Gonzalez-Velasco (1992). "Connections in Mathematical Analysis: The Case of Fourier Series". American Mathematical Monthly. 99 (5): 427–441. doi:10.2307/2325087. JSTOR 2325087.
  • Fetter, Alexander L.; Walecka, John Dirk (2003). Theoretical Mechanics of Particles and Continua. Courier. ISBN 978-0-486-43261-8.
  • Felix Klein, Development of mathematics in the 19th century. Mathsci Press Brookline, Mass, 1979. Translated by M. Ackerman from Vorlesungen über die Entwicklung der Mathematik im 19 Jahrhundert, Springer, Berlin, 1928.
  • Walter Rudin (1976). Principles of mathematical analysis (3rd ed.). New York: McGraw-Hill, Inc. ISBN 0-07-054235-X.
  • A. Zygmund (2002). Trigonometric Series (third ed.). Cambridge: Cambridge University Press. ISBN 0-521-89053-5. The first edition was published in 1935.
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