Fourier Shift Theorem
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A Fourier transform (FT) is a
mathematical Mathematics is an area of knowledge that includes the topics of numbers, formulas and related structures, shapes and the spaces in which they are contained, and quantities and their changes. These topics are represented in modern mathematics ...
transform Transform may refer to: Arts and entertainment * Transform (scratch), a type of scratch used by turntablists * ''Transform'' (Alva Noto album), 2001 * ''Transform'' (Howard Jones album) or the title song, 2019 * ''Transform'' (Powerman 5000 album ...
that decomposes functions into frequency components, which are represented by the output of the transform as a function of frequency. Most commonly functions of
time Time is the continued sequence of existence and events that occurs in an apparently irreversible succession from the past, through the present, into the future. It is a component quantity of various measurements used to sequence events, ...
or
space Space is the boundless three-dimensional extent in which objects and events have relative position and direction. In classical physics, physical space is often conceived in three linear dimensions, although modern physicists usually cons ...
are transformed, which will output a function depending on
temporal frequency Frequency is the number of occurrences of a repeating event per unit of time. It is also occasionally referred to as ''temporal frequency'' for clarity, and is distinct from ''angular frequency''. Frequency is measured in hertz (Hz) which is eq ...
or
spatial frequency In mathematics, physics, and engineering, spatial frequency is a characteristic of any structure that is periodic across position in space. The spatial frequency is a measure of how often sinusoidal components (as determined by the Fourier tra ...
respectively. That process is also called ''
analysis Analysis ( : analyses) is the process of breaking a complex topic or substance into smaller parts in order to gain a better understanding of it. The technique has been applied in the study of mathematics and logic since before Aristotle (3 ...
''. An example application would be decomposing the
waveform In electronics, acoustics, and related fields, the waveform of a signal is the shape of its graph as a function of time, independent of its time and magnitude scales and of any displacement in time.David Crecraft, David Gorham, ''Electro ...
of a musical chord into terms of the intensity of its constituent pitches. The term ''Fourier transform'' refers to both the
frequency domain In physics, electronics, control systems engineering, and statistics, the frequency domain refers to the analysis of mathematical functions or signals with respect to frequency, rather than time. Put simply, a time-domain graph shows how a s ...
representation and the
mathematical operation In mathematics, an operation is a Function (mathematics), function which takes zero or more input values (also called "''operands''" or "arguments") to a well-defined output value. The number of operands is the arity of the operation. The most c ...
that associates the frequency domain representation to a function of space or time. The Fourier transform of a function is a
complex-valued function Complex analysis, traditionally known as the theory of functions of a complex variable, is the branch of mathematical analysis that investigates functions of complex numbers. It is helpful in many branches of mathematics, including algebrai ...
representing the complex sinusoids that comprise the original function. For each frequency, the magnitude ( absolute value) of the
complex value In mathematics, a complex number is an element of a number system that extends the real numbers with a specific element denoted , called the imaginary unit and satisfying the equation i^= -1; every complex number can be expressed in the form ...
represents the
amplitude The amplitude of a periodic variable is a measure of its change in a single period (such as time or spatial period). The amplitude of a non-periodic signal is its magnitude compared with a reference value. There are various definitions of am ...
of a constituent complex sinusoid with that frequency, and the argument of the complex value represents that complex sinusoid's
phase offset In physics and mathematics, the phase of a periodic function F of some real variable t (such as time) is an angle-like quantity representing the fraction of the cycle covered up to t. It is denoted \phi(t) and expressed in such a scale that it v ...
. If a frequency is not present, the transform has a value of 0 for that frequency. The Fourier transform is not limited to functions of time, but the
domain Domain may refer to: Mathematics *Domain of a function, the set of input values for which the (total) function is defined **Domain of definition of a partial function **Natural domain of a partial function **Domain of holomorphy of a function * Do ...
of the original function is commonly referred to as the ''
time domain Time domain refers to the analysis of mathematical functions, physical signals or time series of economic or environmental data, with respect to time. In the time domain, the signal or function's value is known for all real numbers, for the c ...
''. The Fourier inversion theorem provides a ''synthesis'' process that recreates the original function from its frequency domain representation. Functions that are localized in the time domain have Fourier transforms that are spread out across the frequency domain and vice versa, a phenomenon known as the
uncertainty principle In quantum mechanics, the uncertainty principle (also known as Heisenberg's uncertainty principle) is any of a variety of mathematical inequalities asserting a fundamental limit to the accuracy with which the values for certain pairs of physic ...
. The
critical Critical or Critically may refer to: *Critical, or critical but stable, medical states **Critical, or intensive care medicine *Critical juncture, a discontinuous change studied in the social sciences. *Critical Software, a company specializing in ...
case for this principle is the
Gaussian function In mathematics, a Gaussian function, often simply referred to as a Gaussian, is a function of the base form f(x) = \exp (-x^2) and with parametric extension f(x) = a \exp\left( -\frac \right) for arbitrary real constants , and non-zero . It is ...
, of substantial importance in
probability theory Probability theory is the branch of mathematics concerned with probability. Although there are several different probability interpretations, probability theory treats the concept in a rigorous mathematical manner by expressing it through a set ...
and statistics as well as in the study of physical phenomena exhibiting
normal distribution In statistics, a normal distribution or Gaussian distribution is a type of continuous probability distribution for a real-valued random variable. The general form of its probability density function is : f(x) = \frac e^ The parameter \mu ...
(e.g.,
diffusion Diffusion is the net movement of anything (for example, atoms, ions, molecules, energy) generally from a region of higher concentration to a region of lower concentration. Diffusion is driven by a gradient in Gibbs free energy or chemical p ...
). The Fourier transform of a Gaussian function is another Gaussian function.
Joseph Fourier Jean-Baptiste Joseph Fourier (; ; 21 March 1768 – 16 May 1830) was a French people, French mathematician and physicist born in Auxerre and best known for initiating the investigation of Fourier series, which eventually developed into Fourier an ...
introduced the transform in his study of
heat transfer Heat transfer is a discipline of thermal engineering that concerns the generation, use, conversion, and exchange of thermal energy (heat) between physical systems. Heat transfer is classified into various mechanisms, such as thermal conduction, ...
, where Gaussian functions appear as solutions of the
heat equation In mathematics and physics, the heat equation is a certain partial differential equation. Solutions of the heat equation are sometimes known as caloric functions. The theory of the heat equation was first developed by Joseph Fourier in 1822 for t ...
. The Fourier transform can be formally defined as an improper
Riemann integral In the branch of mathematics known as real analysis, the Riemann integral, created by Bernhard Riemann, was the first rigorous definition of the integral of a function on an interval. It was presented to the faculty at the University of Göt ...
, making it an
integral transform In mathematics, an integral transform maps a function from its original function space into another function space via integration, where some of the properties of the original function might be more easily characterized and manipulated than in ...
, although this definition is not suitable for many applications requiring a more sophisticated integration theory.Depending on the application a
Lebesgue integral In mathematics, the integral of a non-negative function of a single variable can be regarded, in the simplest case, as the area between the graph of that function and the -axis. The Lebesgue integral, named after French mathematician Henri Lebe ...
, distributional, or other approach may be most appropriate.
For example, many relatively simple applications use the
Dirac delta function In mathematics, the Dirac delta distribution ( distribution), also known as the unit impulse, is a generalized function or distribution over the real numbers, whose value is zero everywhere except at zero, and whose integral over the entire ...
, which can be treated formally as if it were a function, but the justification requires a mathematically more sophisticated viewpoint. provides solid justification for these formal procedures without going too deeply into
functional analysis Functional analysis is a branch of mathematical analysis, the core of which is formed by the study of vector spaces endowed with some kind of limit-related structure (e.g. Inner product space#Definition, inner product, Norm (mathematics)#Defini ...
or the
theory of distributions A theory is a rational type of abstract thinking about a phenomenon, or the results of such thinking. The process of contemplative and rational thinking is often associated with such processes as observational study or research. Theories may be s ...
.
The Fourier transform can also be generalized to functions of several variables on Euclidean space, sending a function of 'position space' to a function of momentum (or a function of space and time to a function of
4-momentum In special relativity, four-momentum (also called momentum-energy or momenergy ) is the generalization of the classical three-dimensional momentum to four-dimensional spacetime. Momentum is a vector in three dimensions; similarly four-momentum i ...
). This idea makes the spatial Fourier transform very natural in the study of waves, as well as in
quantum mechanics Quantum mechanics is a fundamental theory in physics that provides a description of the physical properties of nature at the scale of atoms and subatomic particles. It is the foundation of all quantum physics including quantum chemistry, ...
, where it is important to be able to represent wave solutions as functions of either position or momentum and sometimes both. In general, functions to which Fourier methods are applicable are complex-valued, and possibly vector-valued.In
relativistic quantum mechanics In physics, relativistic quantum mechanics (RQM) is any Poincaré covariant formulation of quantum mechanics (QM). This theory is applicable to massive particles propagating at all velocities up to those comparable to the speed of light ''c ...
one encounters vector-valued Fourier transforms of multi-component wave functions. In
quantum field theory In theoretical physics, quantum field theory (QFT) is a theoretical framework that combines classical field theory, special relativity, and quantum mechanics. QFT is used in particle physics to construct physical models of subatomic particles and ...
, operator-valued Fourier transforms of operator-valued functions of spacetime are in frequent use, see for example .
Still further generalization is possible to functions on
groups A group is a number of persons or things that are located, gathered, or classed together. Groups of people * Cultural group, a group whose members share the same cultural identity * Ethnic group, a group whose members share the same ethnic iden ...
, which, besides the original Fourier transform on or (viewed as groups under addition), notably includes the
discrete-time Fourier transform In mathematics, the discrete-time Fourier transform (DTFT) is a form of Fourier analysis that is applicable to a sequence of values. The DTFT is often used to analyze samples of a continuous function. The term ''discrete-time'' refers to the ...
(DTFT, group = ), the
discrete Fourier transform In mathematics, the discrete Fourier transform (DFT) converts a finite sequence of equally-spaced samples of a function into a same-length sequence of equally-spaced samples of the discrete-time Fourier transform (DTFT), which is a complex- ...
(DFT, group = ) and the
Fourier series A Fourier series () is a summation of harmonically related sinusoidal functions, also known as components or harmonics. The result of the summation is a periodic function whose functional form is determined by the choices of cycle length (or ''p ...
or circular Fourier transform (group = , the unit circle ≈ closed finite interval with endpoints identified). The latter is routinely employed to handle
periodic function A periodic function is a function that repeats its values at regular intervals. For example, the trigonometric functions, which repeat at intervals of 2\pi radians, are periodic functions. Periodic functions are used throughout science to desc ...
s. The
fast Fourier transform A fast Fourier transform (FFT) is an algorithm that computes the discrete Fourier transform (DFT) of a sequence, or its inverse (IDFT). Fourier analysis converts a signal from its original domain (often time or space) to a representation in th ...
(FFT) is an algorithm for computing the DFT.


Definitions


The analysis formula

The Fourier transform is an extension of the
Fourier series A Fourier series () is a summation of harmonically related sinusoidal functions, also known as components or harmonics. The result of the summation is a periodic function whose functional form is determined by the choices of cycle length (or ''p ...
, which in its most general form introduces the use of complex exponential functions. For example, for a function f(x), the amplitude and phase of a frequency component at frequency n/P, n \in \mathbb Z, is given by this complex number: :c_n = \tfrac \int_P f(x) \, e^ \, dx. The extension provides a frequency continuum of components \left(\xi \in \mathbb R\right), using an infinite integral of integration: Here, the transform of function f(x) at frequency \xi is denoted by the complex number \hat(\xi), which is just one of several common conventions. Evaluating for all values of \xi produces the ''frequency-domain'' function. When the independent variable (x) represents ''time'' (often denoted by t), the transform variable (\xi) represents
frequency Frequency is the number of occurrences of a repeating event per unit of time. It is also occasionally referred to as ''temporal frequency'' for clarity, and is distinct from ''angular frequency''. Frequency is measured in hertz (Hz) which is eq ...
(often denoted by f). For example, if time is measured in
seconds The second (symbol: s) is the unit of time in the International System of Units (SI), historically defined as of a day – this factor derived from the division of the day first into 24 hours, then to 60 minutes and finally to 60 seconds ...
, then frequency is in
hertz The hertz (symbol: Hz) is the unit of frequency in the International System of Units (SI), equivalent to one event (or cycle) per second. The hertz is an SI derived unit whose expression in terms of SI base units is s−1, meaning that on ...
. A key to interpreting is that the effect of multiplying f(x) by e^ is to subtract \xi from every frequency component of function f(x).A possible source of confusion is the frequency-shifting property; i.e. the transform of function f(x)e^ is \hat(\xi+\xi_0).  The value of this function at  \xi=0  is \hat(\xi_0), meaning that a frequency \xi_0 has been shifted to zero. (also see
Negative frequency The concept of signed frequency (negative and positive frequency) can indicate both the rate and sense of rotation; it can be as simple as a wheel rotating clockwise or counterclockwise. The rate is expressed in units such as revolutions (a.k.a. ''c ...
) So the component that was at \xi ends up at zero hertz, and the integral produces its amplitude, because all the other components are oscillatory and integrate to zero over an infinite interval. The functions f and \hat are often referred to as a ''Fourier transform pair''.  A common notation for designating transform pairs is: :f(x)\ \stackrel\ \hat f(\xi)\quad \text\quad \operatorname(x)\ \stackrel\ \operatorname(\xi) Fourier series cannot represent ''non-periodic'' waveforms. However, the Fourier transform is able to represent ''non-periodic'' waveforms as well. It achieves this by applying a limiting process to lengthen the period of any waveform to
infinity Infinity is that which is boundless, endless, or larger than any natural number. It is often denoted by the infinity symbol . Since the time of the ancient Greeks, the philosophical nature of infinity was the subject of many discussions amo ...
and then treating that as a periodic waveform.


The synthesis formula

The actual Fourier series is a synthesis formula: :f(x) = \sum_^\infty c_n\, e^. And the Fourier transform extension is:The complex number, \hat(\xi), conveys both amplitude and phase of frequency \xi. So is a representation of f(x) as a weighted summation of complex exponential functions. This is known as the Fourier inversion theorem, and was first introduced in Fourier's ''Analytical Theory of Heat'', although a proof by modern standards was not given until much later.


Other notational conventions

For other common conventions and notations, including using the
angular frequency In physics, angular frequency "''ω''" (also referred to by the terms angular speed, circular frequency, orbital frequency, radian frequency, and pulsatance) is a scalar measure of rotation rate. It refers to the angular displacement per unit tim ...
instead of the
ordinary frequency Frequency is the number of occurrences of a repeating event per unit of time. It is also occasionally referred to as ''temporal frequency'' for clarity, and is distinct from ''angular frequency''. Frequency is measured in hertz (Hz) which is eq ...
, see Other conventions and Other notations below. The Fourier transform on Euclidean space is treated separately, in which the variable often represents position and momentum. The conventions chosen in this article are those of
harmonic analysis Harmonic analysis is a branch of mathematics concerned with the representation of Function (mathematics), functions or signals as the Superposition principle, superposition of basic waves, and the study of and generalization of the notions of Fo ...
, and are characterized as the unique conventions such that the Fourier transform is both
unitary Unitary may refer to: Mathematics * Unitary divisor * Unitary element * Unitary group * Unitary matrix * Unitary morphism * Unitary operator * Unitary transformation * Unitary representation * Unitarity (physics) * ''E''-unitary inverse semigrou ...
on and an algebra homomorphism from to , without renormalizing the Lebesgue measure. Many other characterizations of the Fourier transform exist. For example, one uses the
Stone–von Neumann theorem In mathematics and in theoretical physics, the Stone–von Neumann theorem refers to any one of a number of different formulations of the uniqueness of the canonical commutation relations between position and momentum operators. It is named after ...
: the Fourier transform is the unique unitary
intertwiner In mathematics, equivariance is a form of symmetry for functions from one space with symmetry to another (such as symmetric spaces). A function is said to be an equivariant map when its domain and codomain are acted on by the same symmetry grou ...
for the symplectic and Euclidean Schrödinger representations of the
Heisenberg group In mathematics, the Heisenberg group H, named after Werner Heisenberg, is the group of 3×3 upper triangular matrices of the form ::\begin 1 & a & c\\ 0 & 1 & b\\ 0 & 0 & 1\\ \end under the operation of matrix multiplication. Elements ' ...
.


Background


History

In 1822, Fourier claimed (see ) that any function, whether continuous or discontinuous, can be expanded into a series of sines. That important work was corrected and expanded upon by others to provide the foundation for the various forms of the Fourier transform used since.


Use of complex sinusoids to represent real sinusoids

To simplify the math, it is desirable to write the Fourier series as a sum of
complex exponentials The exponential function is a mathematical function denoted by f(x)=\exp(x) or e^x (where the argument is written as an exponent). Unless otherwise specified, the term generally refers to the positive-valued function of a real variable, a ...
(see ). Each complex exponential or ''complex sinusoid'' of frequency can be expressed using
Euler's formula Euler's formula, named after Leonhard Euler, is a mathematical formula in complex analysis that establishes the fundamental relationship between the trigonometric functions and the complex exponential function. Euler's formula states that for an ...
as the sum of a cosine wave of frequency for the real component plus a sine wave also of frequency for the imaginary component: :\begin e^ &= \cos(2\pi \xi x) + i \sin(2\pi \xi x) \end Expressing real sinusoids as complex sinusoids makes it necessary for the Fourier coefficients c_nto be complex valued, but has the benefit of compactly representing all necessary information about each frequency. The usual interpretation of this complex number is that \left\vert c_n \right\vert (its
magnitude Magnitude may refer to: Mathematics *Euclidean vector, a quantity defined by both its magnitude and its direction *Magnitude (mathematics), the relative size of an object *Norm (mathematics), a term for the size or length of a vector *Order of ...
) gives the
amplitude The amplitude of a periodic variable is a measure of its change in a single period (such as time or spatial period). The amplitude of a non-periodic signal is its magnitude compared with a reference value. There are various definitions of am ...
and \arg (c_n) (its
argument An argument is a statement or group of statements called premises intended to determine the degree of truth or acceptability of another statement called conclusion. Arguments can be studied from three main perspectives: the logical, the dialectic ...
) gives the
phase Phase or phases may refer to: Science *State of matter, or phase, one of the distinct forms in which matter can exist *Phase (matter), a region of space throughout which all physical properties are essentially uniform * Phase space, a mathematic ...
of the complex sinusoid for that coefficient. These complex exponentials may have
negative frequency The concept of signed frequency (negative and positive frequency) can indicate both the rate and sense of rotation; it can be as simple as a wheel rotating clockwise or counterclockwise. The rate is expressed in units such as revolutions (a.k.a. ''c ...
. For example, both complex sinusoids and complete one cycle per unit of , but the first represents a positive frequency while the second represents a negative frequency. Positive frequency can be understood as rotating counter-clockwise about the
complex plane In mathematics, the complex plane is the plane formed by the complex numbers, with a Cartesian coordinate system such that the -axis, called the real axis, is formed by the real numbers, and the -axis, called the imaginary axis, is formed by the ...
while negative frequency can be understood as rotating clockwise about the complex plane. When complex sinusoids are interpreted as a
helix A helix () is a shape like a corkscrew or spiral staircase. It is a type of smooth space curve with tangent lines at a constant angle to a fixed axis. Helices are important in biology, as the DNA molecule is formed as two intertwined helices, ...
in three-dimensions (with the third dimension being the imaginary component), negating the frequency simply changes the handedness of the helix. Real sine and cosine waves can be recovered from the complex exponential representation of sinusoids. For example, a corollary to Euler's formula allows expressing cosine and sine waves as either the real or imaginary part of a complex sinusoid or as a
weighted sum A weight function is a mathematical device used when performing a sum, integral, or average to give some elements more "weight" or influence on the result than other elements in the same set. The result of this application of a weight function is ...
of two complex sinusoids of opposite frequency: :\begin \cos(2\pi \xi x) &= \operatorname \left(e^\right) =\tfrac e^ + \tfrac e^, \\ \sin(2\pi \xi x) &= \operatorname \left(e^\right) =\tfrac e^ - \tfrac e^. \end Consequently, a general form of any real sinusoid (with frequency , phase shift , and amplitude ) can be expressed as the sum of two complex sinusoids of opposite frequency ( and -) but equal magnitude () and with the phase shift embedded in both their complex coefficients: :\begin A \cos(2\pi \xi x + \theta) &= \tfrac e^ + \tfrac e^ = \tfrac e^ + \tfrac e^ . \end Hence, every real sinusoid (and real signal) can be considered to consist of a positive and negative frequency, whose imaginary components cancel but whose real components contribute equally to form the real signal. To avoid the use of complex numbers and negative frequencies, the
sine and cosine transforms In mathematics, the Fourier sine and cosine transforms are forms of the Fourier transform that do not use complex numbers or require negative frequency. They are the forms originally used by Joseph Fourier and are still preferred in some application ...
together can be used as an equivalent alternative form of the Fourier transform.


Fourier transform for functions that are zero outside an interval

There is a close connection between the definition of
Fourier series A Fourier series () is a summation of harmonically related sinusoidal functions, also known as components or harmonics. The result of the summation is a periodic function whose functional form is determined by the choices of cycle length (or ''p ...
and the Fourier transform for functions that are zero outside an interval. For such a function, we can calculate its Fourier series on any interval that includes the points where is not zero. The Fourier transform is also defined for such a function. As we increase the length of the interval in which we calculate the Fourier series, then the Fourier series coefficients begin to resemble the Fourier transform and the sum of the Fourier series of begins to resemble the inverse Fourier transform. More precisely, suppose is large enough that the interval contains the interval in which is not zero. Then, the th series coefficient is given by: :c_n = \frac \int_^\frac f(x)\, e^ \, dx. Comparing this to the definition of the Fourier transform, it follows that: :c_n = \frac\hat f\left(\frac\right) since is zero outside . Thus, the Fourier coefficients are equal to the values of the Fourier transform sampled on a grid of width , multiplied by the grid width . Under appropriate conditions, the Fourier series of will equal the function . In other words, can be written: :f(x)=\sum_^\infty c_n\, e^ =\sum_^\infty \hat(\xi_n)\ e^\Delta\xi, where the last sum is simply the first sum rewritten using the definitions , and . This second sum is a
Riemann sum In mathematics, a Riemann sum is a certain kind of approximation of an integral by a finite sum. It is named after nineteenth century German mathematician Bernhard Riemann. One very common application is approximating the area of functions or lin ...
. By letting it will converge to the integral for the inverse Fourier transform as expressed above. Under suitable conditions, this argument may be made precise..


Fourier transform for periodic functions

The following is a Fourier transform pair (see Dirac_delta_function#Fourier_transform): :e^\ \stackrel\ \delta \left(\xi - \xi_0\right) It follows that a P-periodic function with convergent Fourier series: : f(x) = \sum_^\infty c_n \cdot e^ has the Fourier transform: : \begin \hat(\xi) &= \sum_^\infty c_n \cdot \mathcal \left \\\ &= \sum_^\infty c_n \cdot \delta \left(\xi - \tfrac\right), \end which is a
Dirac comb In mathematics, a Dirac comb (also known as shah function, impulse train or sampling function) is a periodic function with the formula \operatorname_(t) \ := \sum_^ \delta(t - k T) for some given period T. Here ''t'' is a real variable and the ...
function whose ''teeth'' are modulated by the Fourier series coefficients.


Example

The following figures provide a visual illustration how the Fourier transform measures whether a frequency is present in a particular function. The depicted function oscillates at 3  Hz (if measures seconds) and tends quickly to 0. (The second factor in this equation is an envelope function that shapes the continuous sinusoid into a short pulse. Its general form is a
Gaussian function In mathematics, a Gaussian function, often simply referred to as a Gaussian, is a function of the base form f(x) = \exp (-x^2) and with parametric extension f(x) = a \exp\left( -\frac \right) for arbitrary real constants , and non-zero . It is ...
). This function was specially chosen to have a real Fourier transform that can be easily plotted. The first image contains its graph. In order to calculate \hat(3) we must integrate . The second image shows the plot of the real and imaginary parts of this function. The real part of the integrand is almost always positive, because when is negative, the real part of is negative as well. Because they oscillate at the same rate, when is positive, so is the real part of . The result is that when you integrate the real part of the integrand you get a relatively large number (in this case ). On the other hand, when you try to measure a frequency that is not present, as in the case when we look at \hat(5), you see that both real and imaginary component of this function vary rapidly between positive and negative values, as plotted in the third image. Therefore, in this case, the integrand oscillates fast enough so that the integral is very small and the value for the Fourier transform for that frequency is nearly zero. The general situation may be a bit more complicated than this, but this in spirit is how the Fourier transform measures how much of an individual frequency is present in a function . File:Function ocsillating at 3 hertz.svg, Original function showing oscillation 3 Hz. File:Onfreq.svg, Real and imaginary parts of integrand for Fourier transform at 3 Hz File:Offfreq.svg, Real and imaginary parts of integrand for Fourier transform at 5 Hz File:Fourier transform of oscillating function.svg, Magnitude of Fourier transform, with 3 and 5 Hz labeled.


Properties of the Fourier transform

Here we assume , and are ''integrable functions'':
Lebesgue-measurable In measure theory, a branch of mathematics, the Lebesgue measure, named after French mathematician Henri Lebesgue, is the standard way of assigning a measure to subsets of ''n''-dimensional Euclidean space. For ''n'' = 1, 2, or 3, it coincides wit ...
on the real line satisfying: \int_^\infty , f(x), \, dx < \infty. We denote the Fourier transforms of these functions as , and respectively.


Basic properties

The Fourier transform has the following basic properties:.


Linearity

: For any
complex number In mathematics, a complex number is an element of a number system that extends the real numbers with a specific element denoted , called the imaginary unit and satisfying the equation i^= -1; every complex number can be expressed in the form ...
s and , if , then .


Translation / time shifting

: For any
real number In mathematics, a real number is a number that can be used to measure a ''continuous'' one-dimensional quantity such as a distance, duration or temperature. Here, ''continuous'' means that values can have arbitrarily small variations. Every real ...
, if , then .


Modulation / frequency shifting

: For any
real number In mathematics, a real number is a number that can be used to measure a ''continuous'' one-dimensional quantity such as a distance, duration or temperature. Here, ''continuous'' means that values can have arbitrarily small variations. Every real ...
, if , then .


Time scaling

: For a non-zero
real number In mathematics, a real number is a number that can be used to measure a ''continuous'' one-dimensional quantity such as a distance, duration or temperature. Here, ''continuous'' means that values can have arbitrarily small variations. Every real ...
, if , then : \hat(\xi)=\frac\hat\left(\frac\right). :The case leads to the ''time-reversal'' property, which states: if , then .


Symmetry

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: \begin \mathsf \quad &\ f \quad &= \quad & f_ \quad &+ \quad & f_ \quad &+ \quad i\ & f_ \quad &+ \quad &\underbrace \\ &\Bigg\Updownarrow\mathcal & &\Bigg\Updownarrow\mathcal & &\ \ \Bigg\Updownarrow\mathcal & &\ \ \Bigg\Updownarrow\mathcal & &\ \ \Bigg\Updownarrow\mathcal\\ \mathsf \quad &\hat f \quad &= \quad & \hat f_ \quad &+ \quad &\overbrace \quad &+ \quad i\ & \hat f_ \quad &+ \quad & \hat f_ \end From this, various relationships are apparent, for example: *The transform of a real-valued function () is the even symmetric function . Conversely, an even-symmetric transform implies a real-valued time-domain. *The transform of an imaginary-valued function () is the odd symmetric function , and the converse is true. *The transform of an even-symmetric function () is the real-valued function , and the converse is true. *The transform of an odd-symmetric function () is the imaginary-valued function , and the converse is true.


Conjugation Conjugation or conjugate may refer to: Linguistics * Grammatical conjugation, the modification of a verb from its basic form * Emotive conjugation or Russell's conjugation, the use of loaded language Mathematics * Complex conjugation, the chang ...

: If , then : \hat(\xi) = \overline. : In particular, if is real, then one has the ''reality condition'' : \hat(-\xi)=\overline, : that is, is a
Hermitian function In mathematical analysis, a Hermitian function is a complex function with the property that its complex conjugate is equal to the original function with the variable changed in sign: :f^*(x) = f(-x) (where the ^* indicates the complex conjugate) ...
. And if is purely imaginary, then : \hat(-\xi)=-\hat(\xi).


Real and imaginary part in time

* If h(x) = \Re, then \hat(\xi) = \frac\left(\hat(\xi) + \overline\right). * If h(x) = \Im, then \hat(\xi) = \frac\left(\hat(\xi) - \overline\right).


The zero frequency component

: Substituting in the definition, we obtain : \hat(0) = \int_^ f(x)\,dx. : That is the same as the integral of over all its domain and is also known as the average value or
DC bias In signal processing, when describing a periodic function in the time domain, the DC bias, DC component, DC offset, or DC coefficient is the mean amplitude of the waveform. If the mean amplitude is zero, there is no DC bias. A waveform with no DC ...
of the function.


Invertibility and periodicity

Under suitable conditions on the function f, it can be recovered from its Fourier transform \hat. Indeed, denoting the Fourier transform operator by \mathcal, so \mathcal f := \hat, then for suitable functions, applying the Fourier transform twice simply flips the function: (\mathcal^2 f)(x) = f(-x), which can be interpreted as "reversing time". Since reversing time is two-periodic, applying this twice yields \mathcal^4(f) = f, so the Fourier transform operator is four-periodic, and similarly the inverse Fourier transform can be obtained by applying the Fourier transform three times: \mathcal^3(\hat) = f. In particular the Fourier transform is invertible (under suitable conditions). More precisely, defining the ''parity operator'' \mathcal such that (\mathcal f)(x) = f(-x), we have: : \begin \mathcal^0 &= \mathrm, \\ \mathcal^1 &= \mathcal, \\ \mathcal^2 &= \mathcal, \\ \mathcal^3 &= \mathcal^ = \mathcal \circ \mathcal = \mathcal \circ \mathcal, \\ \mathcal^4 &= \mathrm \end These equalities of operators require careful definition of the space of functions in question, defining equality of functions (equality at every point? equality
almost everywhere In measure theory (a branch of mathematical analysis), a property holds almost everywhere if, in a technical sense, the set for which the property holds takes up nearly all possibilities. The notion of "almost everywhere" is a companion notion to ...
?) and defining equality of operators – that is, defining the topology on the function space and operator space in question. These are not true for all functions, but are true under various conditions, which are the content of the various forms of the Fourier inversion theorem. This fourfold periodicity of the Fourier transform is similar to a rotation of the plane by 90°, particularly as the two-fold iteration yields a reversal, and in fact this analogy can be made precise. While the Fourier transform can simply be interpreted as switching the time domain and the frequency domain, with the inverse Fourier transform switching them back, more geometrically it can be interpreted as a rotation by 90° in the time–frequency domain (considering time as the -axis and frequency as the -axis), and the Fourier transform can be generalized to the
fractional Fourier transform In mathematics, in the area of harmonic analysis, the fractional Fourier transform (FRFT) is a family of linear transformations generalizing the Fourier transform. It can be thought of as the Fourier transform to the ''n''-th power, where ''n'' n ...
, which involves rotations by other angles. This can be further generalized to
linear canonical transformation In Hamiltonian mechanics, the linear canonical transformation (LCT) is a family of integral transforms that generalizes many classical transforms. It has 4 parameters and 1 constraint, so it is a 3-dimensional family, and can be visualized as the ac ...
s, which can be visualized as the action of the
special linear group In mathematics, the special linear group of degree ''n'' over a field ''F'' is the set of matrices with determinant 1, with the group operations of ordinary matrix multiplication and matrix inversion. This is the normal subgroup of the genera ...
on the time–frequency plane, with the preserved symplectic form corresponding to the
uncertainty principle In quantum mechanics, the uncertainty principle (also known as Heisenberg's uncertainty principle) is any of a variety of mathematical inequalities asserting a fundamental limit to the accuracy with which the values for certain pairs of physic ...
, below. This approach is particularly studied in
signal processing Signal processing is an electrical engineering subfield that focuses on analyzing, modifying and synthesizing ''signals'', such as audio signal processing, sound, image processing, images, and scientific measurements. Signal processing techniq ...
, under
time–frequency analysis In signal processing, time–frequency analysis comprises those techniques that study a signal in both the time and frequency domains ''simultaneously,'' using various time–frequency representations. Rather than viewing a 1-dimensional signal (a ...
.


Units and duality

The frequency variable must have inverse units to the units of the original function's domain (typically named or ). For example, if is measured in seconds, should be in cycles per second. If the scale of time is in units of 2 seconds, then another greek letter typically is used instead to represent
angular frequency In physics, angular frequency "''ω''" (also referred to by the terms angular speed, circular frequency, orbital frequency, radian frequency, and pulsatance) is a scalar measure of rotation rate. It refers to the angular displacement per unit tim ...
(where ) in units of
radians The radian, denoted by the symbol rad, is the unit of angle in the International System of Units (SI) and is the standard unit of angular measure used in many areas of mathematics. The unit was formerly an SI supplementary unit (before that c ...
per second. If using for units of length, then must be in inverse length, e.g.,
wavenumber In the physical sciences, the wavenumber (also wave number or repetency) is the ''spatial frequency'' of a wave, measured in cycles per unit distance (ordinary wavenumber) or radians per unit distance (angular wavenumber). It is analogous to temp ...
s. That is to say, there are two versions of the real line: one which is the
range Range may refer to: Geography * Range (geographic), a chain of hills or mountains; a somewhat linear, complex mountainous or hilly area (cordillera, sierra) ** Mountain range, a group of mountains bordered by lowlands * Range, a term used to i ...
of and measured in units of t, and the other which is the range of and measured in inverse units to the units of . These two distinct versions of the real line cannot be equated with each other. Therefore, the Fourier transform goes from one space of functions to a different space of functions: functions which have a different domain of definition. In general, must always be taken to be a
linear form In mathematics, a linear form (also known as a linear functional, a one-form, or a covector) is a linear map from a vector space to its field of scalars (often, the real numbers or the complex numbers). If is a vector space over a field , the s ...
on the space of its domain, which is to say that the second real line is the
dual space In mathematics, any vector space ''V'' has a corresponding dual vector space (or just dual space for short) consisting of all linear forms on ''V'', together with the vector space structure of pointwise addition and scalar multiplication by const ...
of the first real line. See the article on
linear algebra Linear algebra is the branch of mathematics concerning linear equations such as: :a_1x_1+\cdots +a_nx_n=b, linear maps such as: :(x_1, \ldots, x_n) \mapsto a_1x_1+\cdots +a_nx_n, and their representations in vector spaces and through matrices. ...
for a more formal explanation and for more details. This point of view becomes essential in generalisations of the Fourier transform to general
symmetry group In group theory, the symmetry group of a geometric object is the group of all transformations under which the object is invariant, endowed with the group operation of composition. Such a transformation is an invertible mapping of the ambient ...
s, including the case of Fourier series. That there is no one preferred way (often, one says "no canonical way") to compare the two versions of the real line which are involved in the Fourier transform—fixing the units on one line does not force the scale of the units on the other line—is the reason for the plethora of rival conventions on the definition of the Fourier transform. The various definitions resulting from different choices of units differ by various constants. Let \hat f_1(\xi) be the form of the Fourier transform in terms of ordinary frequency . Because \xi = \tfrac, the alternative form \hat f_3(\omega) (which calls the non-unitary form in angular frequency) has no factor in its definition :\begin \hat_3(\omega) \ &\stackrel\ \int_^ f(x)\, e^\, dx = \hat_1 \left(\frac\right) \end but has a factor of \tfrac in its corresponding inversion formula : \begin f(x) &= \frac \int_^ \hat_3(\omega)\, e^\, d\omega . \end An alternative form \hat f_2(\omega) (which calls the unitary form in angular frequency) has a factor of \tfrac in its definition :\begin \hat_2(\omega)\ &\stackrel\ \frac \int_^ f(x)\, e^\, dx \end and also has that same factor of \tfrac in its corresponding inversion formula, producing a symmetrical relationship : \begin f(x) &= \frac \int_^ \hat_2(\omega)\, e^\, d\omega . \end In other conventions, the Fourier transform has in the exponent instead of , and vice versa for the inversion formula. This convention is common in modern physics and is the default fo
Wolfram Alpha
and does not mean that the frequency has become negative, since there is no canonical definition of positivity for frequency of a complex wave. It simply means that \hat f(\xi) is the amplitude of the wave  e^  instead of the wave  e^ (the former, with its minus sign, is often seen in the time dependence for
Sinusoidal plane-wave solutions of the electromagnetic wave equation Sinusoidal plane-wave solutions are particular solutions to the electromagnetic wave equation. The general solution of the electromagnetic wave equation in homogeneous, linear, time-independent media can be written as a linear superposition of ...
, or in the time dependence for quantum wave functions). Many of the identities involving the Fourier transform remain valid in those conventions, provided all terms that explicitly involve have it replaced by . In
Electrical engineering Electrical engineering is an engineering discipline concerned with the study, design, and application of equipment, devices, and systems which use electricity, electronics, and electromagnetism. It emerged as an identifiable occupation in the l ...
the letter is typically used for the
imaginary unit The imaginary unit or unit imaginary number () is a solution to the quadratic equation x^2+1=0. Although there is no real number with this property, can be used to extend the real numbers to what are called complex numbers, using addition an ...
instead of because is used for current. When using dimensionless units, the constant factors might not even be written in the transform definition. For instance, in
probability theory Probability theory is the branch of mathematics concerned with probability. Although there are several different probability interpretations, probability theory treats the concept in a rigorous mathematical manner by expressing it through a set ...
, the characteristic function of the probability density function of a random variable of continuous type is defined without a negative sign in the exponential, and since the units of are ignored, there is no 2 either: :\phi (\lambda) = \int_^\infty f(x) e^ \,dx. (In probability theory, and in mathematical statistics, the use of the Fourier—Stieltjes transform is preferred, because so many random variables are not of continuous type, and do not possess a density function, and one must treat not functions but distributions, i.e., measures which possess "atoms".) From the higher point of view of group characters, which is much more abstract, all these arbitrary choices disappear, as will be explained in the later section of this article, which treats the notion of the Fourier transform of a function on a
locally compact Abelian group In several mathematical areas, including harmonic analysis, topology, and number theory, locally compact abelian groups are abelian groups which have a particularly convenient topology on them. For example, the group of integers (equipped with the ...
.


Uniform continuity and the Riemann–Lebesgue lemma

The Fourier transform may be defined in some cases for non-integrable functions, but the Fourier transforms of integrable functions have several strong properties. The Fourier transform of any integrable function is
uniformly continuous In mathematics, a real function f of real numbers is said to be uniformly continuous if there is a positive real number \delta such that function values over any function domain interval of the size \delta are as close to each other as we want. In ...
and. :\left\, \hat\right\, _\infty \leq \left\, f\right\, _1 By the ''
Riemann–Lebesgue lemma In mathematics, the Riemann–Lebesgue lemma, named after Bernhard Riemann and Henri Lebesgue, states that the Fourier transform or Laplace transform of an ''L''1 function vanishes at infinity. It is of importance in harmonic analysis and asymptot ...
'',. :\hat(\xi) \to 0\text, \xi, \to \infty. However, \hat need not be integrable. For example, the Fourier transform of the
rectangular function The rectangular function (also known as the rectangle function, rect function, Pi function, Heaviside Pi function, gate function, unit pulse, or the normalized boxcar function) is defined as \operatorname(t) = \Pi(t) = \left\{\begin{array}{r ...
, which is integrable, is the
sinc function In mathematics, physics and engineering, the sinc function, denoted by , has two forms, normalized and unnormalized.. In mathematics, the historical unnormalized sinc function is defined for by \operatornamex = \frac. Alternatively, the u ...
, which is not
Lebesgue integrable In mathematics, the integral of a non-negative function of a single variable can be regarded, in the simplest case, as the area between the graph of that function and the -axis. The Lebesgue integral, named after French mathematician Henri Leb ...
, because its
improper integral In mathematical analysis, an improper integral is the limit of a definite integral as an endpoint of the interval(s) of integration approaches either a specified real number or positive or negative infinity; or in some instances as both endpoin ...
s behave analogously to the
alternating harmonic series In mathematics, the harmonic series is the infinite series formed by summing all positive unit fractions: \sum_^\infty\frac = 1 + \frac + \frac + \frac + \frac + \cdots. The first n terms of the series sum to approximately \ln n + \gamma, where ...
, in converging to a sum without being
absolutely convergent In mathematics, an infinite series of numbers is said to converge absolutely (or to be absolutely convergent) if the sum of the absolute values of the summands is finite. More precisely, a real or complex series \textstyle\sum_^\infty a_n is said ...
. It is not generally possible to write the ''inverse transform'' as a
Lebesgue integral In mathematics, the integral of a non-negative function of a single variable can be regarded, in the simplest case, as the area between the graph of that function and the -axis. The Lebesgue integral, named after French mathematician Henri Lebe ...
. However, when both and \hat are integrable, the inverse equality :f(x) = \int_^\infty \hat f(\xi) e^ \, d\xi holds
almost everywhere In measure theory (a branch of mathematical analysis), a property holds almost everywhere if, in a technical sense, the set for which the property holds takes up nearly all possibilities. The notion of "almost everywhere" is a companion notion to ...
. That is, the Fourier transform is
injective In mathematics, an injective function (also known as injection, or one-to-one function) is a function that maps distinct elements of its domain to distinct elements; that is, implies . (Equivalently, implies in the equivalent contrapositiv ...
on . (But if is continuous, then equality holds for every .)


Plancherel theorem and Parseval's theorem

Let and be integrable, and let and be their Fourier transforms. If ''f''(''x'') and ''g''(''x'') are also
square-integrable In mathematics, a square-integrable function, also called a quadratically integrable function or L^2 function or square-summable function, is a real number, real- or complex number, complex-valued measurable function for which the integral of the s ...
, then the Parseval formula follows: : \langle f, g\rangle_ = \int_^ f(x) \overline \,dx = \int_^\infty \hat(\xi) \overline \,d\xi, where the bar denotes
complex conjugation In mathematics, the complex conjugate of a complex number is the number with an equal real part and an imaginary part equal in magnitude but opposite in sign. That is, (if a and b are real, then) the complex conjugate of a + bi is equal to a - ...
. The
Plancherel theorem In mathematics, the Plancherel theorem (sometimes called the Parseval–Plancherel identity) is a result in harmonic analysis, proven by Michel Plancherel in 1910. It states that the integral of a function's squared modulus is equal to the inte ...
, which follows from the above, states that :\, f\, _ = \int_^\infty \left, f(x) \^2\,dx = \int_^\infty \left, \hat(\xi) \^2\,d\xi. Plancherel's theorem makes it possible to extend the Fourier transform, by a continuity argument, to a
unitary operator In functional analysis, a unitary operator is a surjective bounded operator on a Hilbert space that preserves the inner product. Unitary operators are usually taken as operating ''on'' a Hilbert space, but the same notion serves to define the con ...
on . On , this extension agrees with original Fourier transform defined on , thus enlarging the domain of the Fourier transform to (and consequently to for ). Plancherel's theorem has the interpretation in the sciences that the Fourier transform preserves the
energy In physics, energy (from Ancient Greek: ἐνέργεια, ''enérgeia'', “activity”) is the quantitative property that is transferred to a body or to a physical system, recognizable in the performance of work and in the form of heat a ...
of the original quantity. The terminology of these formulas is not quite standardised. Parseval's theorem was proved only for Fourier series, and was first proved by Lyapunov. But Parseval's formula makes sense for the Fourier transform as well, and so even though in the context of the Fourier transform it was proved by Plancherel, it is still often referred to as Parseval's formula, or Parseval's relation, or even Parseval's theorem. See
Pontryagin duality In mathematics, Pontryagin duality is a duality between locally compact abelian groups that allows generalizing Fourier transform to all such groups, which include the circle group (the multiplicative group of complex numbers of modulus one), ...
for a general formulation of this concept in the context of locally compact abelian groups.


Poisson summation formula

The Poisson summation formula (PSF) is an equation that relates the
Fourier series A Fourier series () is a summation of harmonically related sinusoidal functions, also known as components or harmonics. The result of the summation is a periodic function whose functional form is determined by the choices of cycle length (or ''p ...
coefficients of the
periodic summation In signal processing, any periodic function s_P(t) with period ''P'' can be represented by a summation of an infinite number of instances of an aperiodic function s(t), that are offset by integer multiples of ''P''. This representation is called pe ...
of a function to values of the function's continuous Fourier transform. The Poisson summation formula says that for sufficiently regular functions , : \sum_n \hat f(n) = \sum_n f (n). It has a variety of useful forms that are derived from the basic one by application of the Fourier transform's scaling and time-shifting properties. The formula has applications in engineering, physics, and
number theory Number theory (or arithmetic or higher arithmetic in older usage) is a branch of pure mathematics devoted primarily to the study of the integers and arithmetic function, integer-valued functions. German mathematician Carl Friedrich Gauss (1777 ...
. The frequency-domain dual of the standard Poisson summation formula is also called the
discrete-time Fourier transform In mathematics, the discrete-time Fourier transform (DTFT) is a form of Fourier analysis that is applicable to a sequence of values. The DTFT is often used to analyze samples of a continuous function. The term ''discrete-time'' refers to the ...
. Poisson summation is generally associated with the physics of periodic media, such as heat conduction on a circle. The fundamental solution of the heat equation on a circle is called a
theta function In mathematics, theta functions are special functions of several complex variables. They show up in many topics, including Abelian varieties, moduli spaces, quadratic forms, and solitons. As Grassmann algebras, they appear in quantum field theo ...
. It is used in
number theory Number theory (or arithmetic or higher arithmetic in older usage) is a branch of pure mathematics devoted primarily to the study of the integers and arithmetic function, integer-valued functions. German mathematician Carl Friedrich Gauss (1777 ...
to prove the transformation properties of theta functions, which turn out to be a type of
modular form In mathematics, a modular form is a (complex) analytic function on the upper half-plane satisfying a certain kind of functional equation with respect to the Group action (mathematics), group action of the modular group, and also satisfying a grow ...
, and it is connected more generally to the theory of
automorphic form In harmonic analysis and number theory, an automorphic form is a well-behaved function from a topological group ''G'' to the complex numbers (or complex vector space) which is invariant under the action of a discrete subgroup \Gamma \subset G of ...
s where it appears on one side of the
Selberg trace formula In mathematics, the Selberg trace formula, introduced by , is an expression for the character of the unitary representation of a Lie group on the space of square-integrable functions, where is a cofinite discrete group. The character is given b ...
.


Differentiation

Suppose is an absolutely continuous differentiable function, and both and its derivative are integrable. Then the Fourier transform of the derivative is given by :\widehat(\xi) = \mathcal\left\ = 2\pi i\xi\hat(\xi). More generally, the Fourier transformation of the th derivative is given by :\widehat(\xi) = \mathcal\left\ = (2\pi i\xi)^n\hat(\xi). Analogically, \mathcal\left\ = \left(\frac\right)^n \frac \hat(\xi). By applying the Fourier transform and using these formulas, some
ordinary differential equation In mathematics, an ordinary differential equation (ODE) is a differential equation whose unknown(s) consists of one (or more) function(s) of one variable and involves the derivatives of those functions. The term ''ordinary'' is used in contrast w ...
s can be transformed into algebraic equations, which are much easier to solve. These formulas also give rise to the rule of thumb " is smooth
if and only if In logic and related fields such as mathematics and philosophy, "if and only if" (shortened as "iff") is a biconditional logical connective between statements, where either both statements are true or both are false. The connective is bicondi ...
quickly falls to 0 for ." By using the analogous rules for the inverse Fourier transform, one can also say " quickly falls to 0 for if and only if is smooth."


Convolution theorem

The Fourier transform translates between
convolution In mathematics (in particular, functional analysis), convolution is a operation (mathematics), mathematical operation on two function (mathematics), functions ( and ) that produces a third function (f*g) that expresses how the shape of one is ...
and multiplication of functions. If and are integrable functions with Fourier transforms and respectively, then the Fourier transform of the convolution is given by the product of the Fourier transforms and (under other conventions for the definition of the Fourier transform a constant factor may appear). This means that if: :h(x) = (f*g)(x) = \int_^\infty f(y)g(x - y)\,dy, where denotes the convolution operation, then: :\hat(\xi) = \hat(\xi)\, \hat(\xi). In linear time invariant (LTI) system theory, it is common to interpret as the
impulse response In signal processing and control theory, the impulse response, or impulse response function (IRF), of a dynamic system is its output when presented with a brief input signal, called an Dirac delta function, impulse (). More generally, an impulse ...
of an LTI system with input and output , since substituting the
unit impulse Unit may refer to: Arts and entertainment * UNIT, a fictional military organization in the science fiction television series ''Doctor Who'' * Unit of action, a discrete piece of action (or beat) in a theatrical presentation Music * ''Unit'' (al ...
for yields . In this case, represents the
frequency response In signal processing and electronics, the frequency response of a system is the quantitative measure of the magnitude and phase of the output as a function of input frequency. The frequency response is widely used in the design and analysis of sy ...
of the system. Conversely, if can be decomposed as the product of two square integrable functions and , then the Fourier transform of is given by the convolution of the respective Fourier transforms and .


Cross-correlation theorem

In an analogous manner, it can be shown that if is the
cross-correlation In signal processing, cross-correlation is a measure of similarity of two series as a function of the displacement of one relative to the other. This is also known as a ''sliding dot product'' or ''sliding inner-product''. It is commonly used fo ...
of and : :h(x) = (f \star g)(x) = \int_^\infty \overlineg(x + y)\,dy then the Fourier transform of is: :\hat(\xi) = \overline \, \hat(\xi). As a special case, the
autocorrelation Autocorrelation, sometimes known as serial correlation in the discrete time case, is the correlation of a signal with a delayed copy of itself as a function of delay. Informally, it is the similarity between observations of a random variable ...
of function is: :h(x) = (f \star f)(x) = \int_^\infty \overlinef(x + y)\,dy for which :\hat(\xi) = \overline\hat(\xi) = \left, \hat(\xi)\^2.


Eigenfunctions

The Fourier transform is a linear transform which has eigenfunctions obeying \mathcal
psi Psi, PSI or Ψ may refer to: Alphabetic letters * Psi (Greek) (Ψ, ψ), the 23rd letter of the Greek alphabet * Psi (Cyrillic) (Ѱ, ѱ), letter of the early Cyrillic alphabet, adopted from Greek Arts and entertainment * "Psi" as an abbreviatio ...
= \lambda \psi, with \lambda \in \mathbb. A set of eigenfunctions is found by noting that the differentiation rules imply that the
ordinary differential equation In mathematics, an ordinary differential equation (ODE) is a differential equation whose unknown(s) consists of one (or more) function(s) of one variable and involves the derivatives of those functions. The term ''ordinary'' is used in contrast w ...
: \left P\left( \frac\frac \right) + P( x ) \right\psi(x) = C \psi(x) with C constant and P(x) being an even functionThe operator P\left( \frac\frac \right) is defined by the
Taylor series In mathematics, the Taylor series or Taylor expansion of a function is an infinite sum of terms that are expressed in terms of the function's derivatives at a single point. For most common functions, the function and the sum of its Taylor serie ...
of P(x) which features only even powers x^n, n=2,4... because P(x) is even.
remains invariant in form when applying the Fourier transform \mathcal to both sides of the equation. In other words, every solution \psi(x) and its Fourier transform \hat\psi(\xi) obey the same equation. Assuming
uniqueness Uniqueness is a state or condition wherein someone or something is unlike anything else in comparison, or is remarkable, or unusual. When used in relation to humans, it is often in relation to a person's personality, or some specific characterist ...
of the solutions, every solution \psi(x) must therefore be an eigenfunction of the Fourier transform. The simplest example is provided by P(x)=x^2 which is equivalent to the Schrödinger equation for the
quantum harmonic oscillator 量子調和振動子 は、 古典調和振動子 の 量子力学 類似物です。任意の滑らかな ポテンシャル は通常、安定した 平衡点 の近くで 調和ポテンシャル として近似できるため、最 ...
. The corresponding solutions provide an important choice of an orthonormal basis for and are given by the "physicist's"
Hermite functions In mathematics, the Hermite polynomials are a classical orthogonal polynomial sequence. The polynomials arise in: * signal processing as Hermitian wavelets for wavelet transform analysis * probability, such as the Edgeworth series, as well ...
. Equivalently one may use : \psi_n(x) = \frac e^\mathrm_n\left(2x\sqrt\right), where are the "probabilist's"
Hermite polynomial In mathematics, the Hermite polynomials are a classical orthogonal polynomial sequence. The polynomials arise in: * signal processing as Hermitian wavelets for wavelet transform analysis * probability, such as the Edgeworth series, as well as ...
s, defined as : \mathrm_n(x) = (-1)^n e^\left(\frac\right)^n e^. Under this convention for the Fourier transform, we have that : \hat\psi_n(\xi) = (-i)^n \psi_n(\xi). In other words, the Hermite functions form a complete
orthonormal In linear algebra, two vectors in an inner product space are orthonormal if they are orthogonal (or perpendicular along a line) unit vectors. A set of vectors form an orthonormal set if all vectors in the set are mutually orthogonal and all of un ...
system of
eigenfunctions In mathematics, an eigenfunction of a linear operator ''D'' defined on some function space is any non-zero function f in that space that, when acted upon by ''D'', is only multiplied by some scaling factor called an eigenvalue. As an equation, th ...
for the Fourier transform on . However, this choice of eigenfunctions is not unique. Because of \mathcal^4 = \mathrm there are only four different
eigenvalue In linear algebra, an eigenvector () or characteristic vector of a linear transformation is a nonzero vector that changes at most by a scalar factor when that linear transformation is applied to it. The corresponding eigenvalue, often denoted b ...
s of the Fourier transform (the fourth roots of unity ±1 and ±) and any linear combination of eigenfunctions with the same eigenvalue gives another eigenfunction. As a consequence of this, it is possible to decompose as a direct sum of four spaces , , , and where the Fourier transform acts on simply by multiplication by .Incidentally, this also proves that, given any even but possibly highly non-linear P(x) in the differential equation stated above, the resulting solutions \psi(x) may be advantageously decomposed into corresponding linear combinations of Hermite functions. Since the complete set of Hermite functions provides a resolution of the identity they diagonalize the Fourier operator, i.e. the Fourier transform can be represented by such a sum of terms weighted by the above eigenvalues, and these sums can be explicitly summed: :\mathcal \xi) =\int dx f(x) \sum_ (-i)^n \psi_n(x) \psi_n(\xi) ~. This approach to define the Fourier transform was first proposed by
Norbert Wiener Norbert Wiener (November 26, 1894 – March 18, 1964) was an American mathematician and philosopher. He was a professor of mathematics at the Massachusetts Institute of Technology (MIT). A child prodigy, Wiener later became an early researcher i ...
.. Among other properties, Hermite functions decrease exponentially fast in both frequency and time domains, and they are thus used to define a generalization of the Fourier transform, namely the
fractional Fourier transform In mathematics, in the area of harmonic analysis, the fractional Fourier transform (FRFT) is a family of linear transformations generalizing the Fourier transform. It can be thought of as the Fourier transform to the ''n''-th power, where ''n'' n ...
used in time–frequency analysis.. In
physics Physics is the natural science that studies matter, its fundamental constituents, its motion and behavior through space and time, and the related entities of energy and force. "Physical science is that department of knowledge which r ...
, this transform was introduced by
Edward Condon Edward Uhler Condon (March 2, 1902 – March 26, 1974) was an American nuclear physicist, a pioneer in quantum mechanics, and a participant during World War II in the development of radar and, very briefly, of nuclear weapons as part of the ...
. This change of basis functions becomes possible because the Fourier transform is a unitary transform when using the right conventions. Consequently, under the proper conditions it may be expected to result from a self-adjoint generator N via :\mathcal
psi Psi, PSI or Ψ may refer to: Alphabetic letters * Psi (Greek) (Ψ, ψ), the 23rd letter of the Greek alphabet * Psi (Cyrillic) (Ѱ, ѱ), letter of the early Cyrillic alphabet, adopted from Greek Arts and entertainment * "Psi" as an abbreviatio ...
= e^ \psi. The operator N is the
number operator In quantum mechanics, for systems where the total number of particles may not be preserved, the number operator is the observable that counts the number of particles. The number operator acts on Fock space. Let :, \Psi\rangle_\nu=, \phi_1,\phi_2 ...
of the quantum harmonic oscillator written as : N \equiv \frac(x-\frac)(x+\frac) = \frac(-\frac+x^2-1). It can be interpreted as the
generator Generator may refer to: * Signal generator, electronic devices that generate repeating or non-repeating electronic signals * Electric generator, a device that converts mechanical energy to electrical energy. * Generator (circuit theory), an eleme ...
of fractional Fourier transforms for arbitrary values of , and of the conventional continuous Fourier transform \mathcal for the particular value t=\pi/2, with the
Mehler kernel The Mehler kernel is a complex-valued function found to be the propagator of the quantum harmonic oscillator. Mehler's formula defined a function and showed, in modernized notation, that it can be expanded in terms of Hermite polynomials (.) ba ...
implementing the corresponding active transform. The eigenfunctions of N are the
Hermite functions In mathematics, the Hermite polynomials are a classical orthogonal polynomial sequence. The polynomials arise in: * signal processing as Hermitian wavelets for wavelet transform analysis * probability, such as the Edgeworth series, as well ...
\psi_n(x) which are therefore also eigenfunctions of \mathcal. Upon extending the Fourier transform to distributions the
Dirac comb In mathematics, a Dirac comb (also known as shah function, impulse train or sampling function) is a periodic function with the formula \operatorname_(t) \ := \sum_^ \delta(t - k T) for some given period T. Here ''t'' is a real variable and the ...
is also an eigenfunction of the Fourier transform.


Connection with the Heisenberg group

The
Heisenberg group In mathematics, the Heisenberg group H, named after Werner Heisenberg, is the group of 3×3 upper triangular matrices of the form ::\begin 1 & a & c\\ 0 & 1 & b\\ 0 & 0 & 1\\ \end under the operation of matrix multiplication. Elements ' ...
is a certain
group A group is a number of persons or things that are located, gathered, or classed together. Groups of people * Cultural group, a group whose members share the same cultural identity * Ethnic group, a group whose members share the same ethnic iden ...
of
unitary operator In functional analysis, a unitary operator is a surjective bounded operator on a Hilbert space that preserves the inner product. Unitary operators are usually taken as operating ''on'' a Hilbert space, but the same notion serves to define the con ...
s on the
Hilbert space In mathematics, Hilbert spaces (named after David Hilbert) allow generalizing the methods of linear algebra and calculus from (finite-dimensional) Euclidean vector spaces to spaces that may be infinite-dimensional. Hilbert spaces arise natural ...
of square integrable complex valued functions on the real line, generated by the translations and multiplication by , . These operators do not commute, as their (group) commutator is :\left(M^_\xi T^_yM_\xi T_yf\right)(x) = e^f(x) which is multiplication by the constant (independent of ) (the
circle group In mathematics, the circle group, denoted by \mathbb T or \mathbb S^1, is the multiplicative group of all complex numbers with absolute value 1, that is, the unit circle in the complex plane or simply the unit complex numbers. \mathbb T = \ ...
of unit modulus complex numbers). As an abstract group, the Heisenberg group is the three-dimensional
Lie group In mathematics, a Lie group (pronounced ) is a group that is also a differentiable manifold. A manifold is a space that locally resembles Euclidean space, whereas groups define the abstract concept of a binary operation along with the additio ...
of triples , with the group law :\left(x_1, \xi_1, t_1\right) \cdot \left(x_2, \xi_2, t_2\right) = \left(x_1 + x_2, \xi_1 + \xi_2, t_1 t_2 e^\right). Denote the Heisenberg group by . The above procedure describes not only the group structure, but also a standard
unitary representation In mathematics, a unitary representation of a group ''G'' is a linear representation π of ''G'' on a complex Hilbert space ''V'' such that π(''g'') is a unitary operator for every ''g'' ∈ ''G''. The general theory is well-developed in case ''G'' ...
of on a Hilbert space, which we denote by . Define the linear automorphism of by :J \begin x \\ \xi \end = \begin -\xi \\ x \end so that . This can be extended to a unique automorphism of : :j\left(x, \xi, t\right) = \left(-\xi, x, te^\right). According to the
Stone–von Neumann theorem In mathematics and in theoretical physics, the Stone–von Neumann theorem refers to any one of a number of different formulations of the uniqueness of the canonical commutation relations between position and momentum operators. It is named after ...
, the unitary representations and are unitarily equivalent, so there is a unique intertwiner such that :\rho \circ j = W \rho W^*. This operator is the Fourier transform. Many of the standard properties of the Fourier transform are immediate consequences of this more general framework. For example, the square of the Fourier transform, , is an intertwiner associated with , and so we have is the reflection of the original function .


Complex domain

The
integral In mathematics Mathematics is an area of knowledge that includes the topics of numbers, formulas and related structures, shapes and the spaces in which they are contained, and quantities and their changes. These topics are represented i ...
for the Fourier transform : \hat f (\xi) = \int _^\infty e^ f(t) \, dt can be studied for
complex Complex commonly refers to: * Complexity, the behaviour of a system whose components interact in multiple ways so possible interactions are difficult to describe ** Complex system, a system composed of many components which may interact with each ...
values of its argument . Depending on the properties of , this might not converge off the real axis at all, or it might converge to a
complex Complex commonly refers to: * Complexity, the behaviour of a system whose components interact in multiple ways so possible interactions are difficult to describe ** Complex system, a system composed of many components which may interact with each ...
analytic function In mathematics, an analytic function is a function that is locally given by a convergent power series. There exist both real analytic functions and complex analytic functions. Functions of each type are infinitely differentiable, but complex an ...
for all values of , or something in between. The
Paley–Wiener theorem In mathematics, a Paley–Wiener theorem is any theorem that relates decay properties of a function or distribution at infinity with analyticity of its Fourier transform. The theorem is named for Raymond Paley (1907–1933) and Norbert Wiener (189 ...
says that is smooth (i.e., -times differentiable for all positive integers ) and compactly supported if and only if is a
holomorphic function In mathematics, a holomorphic function is a complex-valued function of one or more complex variables that is complex differentiable in a neighbourhood of each point in a domain in complex coordinate space . The existence of a complex derivativ ...
for which there exists a constant such that for any
integer An integer is the number zero (), a positive natural number (, , , etc.) or a negative integer with a minus sign (−1, −2, −3, etc.). The negative numbers are the additive inverses of the corresponding positive numbers. In the language ...
, : \left\vert \xi ^n \hat f(\xi) \right\vert \leq C e^ for some constant . (In this case, is supported on .) This can be expressed by saying that is an
entire function In complex analysis, an entire function, also called an integral function, is a complex-valued function that is holomorphic on the whole complex plane. Typical examples of entire functions are polynomials and the exponential function, and any fin ...
which is
rapidly decreasing In mathematics, a function is said to vanish at infinity if its values approach 0 as the input grows without bounds. There are two different ways to define this with one definition applying to functions defined on normed vector spaces and the other ...
in (for fixed ) and of exponential growth in (uniformly in ). (If is not smooth, but only , the statement still holds provided .) The space of such functions of a
complex variable Complex analysis, traditionally known as the theory of functions of a complex variable, is the branch of mathematical analysis that investigates functions of complex numbers. It is helpful in many branches of mathematics, including algebraic ...
is called the Paley—Wiener space. This theorem has been generalised to semisimple
Lie group In mathematics, a Lie group (pronounced ) is a group that is also a differentiable manifold. A manifold is a space that locally resembles Euclidean space, whereas groups define the abstract concept of a binary operation along with the additio ...
s. If is supported on the half-line , then is said to be "causal" because the
impulse response function In signal processing and control theory, the impulse response, or impulse response function (IRF), of a dynamic system is its output when presented with a brief input signal, called an impulse (). More generally, an impulse response is the reacti ...
of a physically realisable
filter Filter, filtering or filters may refer to: Science and technology Computing * Filter (higher-order function), in functional programming * Filter (software), a computer program to process a data stream * Filter (video), a software component tha ...
must have this property, as no effect can precede its cause. Paley and Wiener showed that then extends to a
holomorphic function In mathematics, a holomorphic function is a complex-valued function of one or more complex variables that is complex differentiable in a neighbourhood of each point in a domain in complex coordinate space . The existence of a complex derivativ ...
on the complex lower half-plane which tends to zero as goes to infinity. The converse is false and it is not known how to characterise the Fourier transform of a causal function.


Laplace transform

The Fourier transform is related to the
Laplace transform In mathematics, the Laplace transform, named after its discoverer Pierre-Simon Laplace (), is an integral transform In mathematics, an integral transform maps a function from its original function space into another function space via integra ...
, which is also used for the solution of
differential equation In mathematics, a differential equation is an equation that relates one or more unknown functions and their derivatives. In applications, the functions generally represent physical quantities, the derivatives represent their rates of change, an ...
s and the analysis of
filter Filter, filtering or filters may refer to: Science and technology Computing * Filter (higher-order function), in functional programming * Filter (software), a computer program to process a data stream * Filter (video), a software component tha ...
s. It may happen that a function for which the Fourier integral does not converge on the real axis at all, nevertheless has a complex Fourier transform defined in some region of the
complex plane In mathematics, the complex plane is the plane formed by the complex numbers, with a Cartesian coordinate system such that the -axis, called the real axis, is formed by the real numbers, and the -axis, called the imaginary axis, is formed by the ...
. For example, if is of exponential growth, i.e., : \vert f(t) \vert < C e^ for some constants , then. : \hat f (i\tau) = \int _^\infty e^ f(t) \, dt, convergent for all , is the
two-sided Laplace transform In mathematics, the two-sided Laplace transform or bilateral Laplace transform is an integral transform equivalent to probability's moment generating function. Two-sided Laplace transforms are closely related to the Fourier transform, the Mellin t ...
of . The more usual version ("one-sided") of the Laplace transform is : F(s) = \int_0^\infty f(t) e^ \, dt. If is also causal, and analytical, then: \hat f(i\tau) = F(-2\pi\tau). Thus, extending the Fourier transform to the complex domain means it includes the Laplace transform as a special case in the case of causal functions—but with the change of variable . From another, perhaps more classical viewpoint, the Laplace transform by its form involves an additional exponential regulating term which lets it converge outside of the imaginary line where the Fourier transform is defined. As such it can converge for at most exponentially divergent series and integrals, whereas the original Fourier decomposition cannot, enabling analysis of systems with divergent or critical elements. Two particular examples from linear signal processing are the construction of allpass filter networks from critical comb and mitigating filters via exact pole-zero cancellation on the unit circle. Such designs are common in audio processing, where highly nonlinear phase response is sought for, as in reverb. Furthermore, when extended pulselike impulse responses are sought for signal processing work, the easiest way to produce them is to have one circuit which produces a divergent time response, and then to cancel its divergence through a delayed opposite and compensatory response. There, only the delay circuit in-between admits a classical Fourier description, which is critical. Both the circuits to the side are unstable, and do not admit a convergent Fourier decomposition. However, they do admit a Laplace domain description, with identical half-planes of convergence in the complex plane (or in the discrete case, the Z-plane), wherein their effects cancel. In modern mathematics the Laplace transform is conventionally subsumed under the aegis Fourier methods. Both of them are subsumed by the far more general, and more abstract, idea of
harmonic analysis Harmonic analysis is a branch of mathematics concerned with the representation of Function (mathematics), functions or signals as the Superposition principle, superposition of basic waves, and the study of and generalization of the notions of Fo ...
.


Inversion

If is complex analytic for , then : \int _^\infty \hat f (\sigma + ia) e^ \, d\sigma = \int _^\infty \hat f (\sigma + ib) e^ \, d\sigma by
Cauchy's integral theorem In mathematics, the Cauchy integral theorem (also known as the Cauchy–Goursat theorem) in complex analysis, named after Augustin-Louis Cauchy (and Édouard Goursat), is an important statement about line integrals for holomorphic functions in t ...
. Therefore, the Fourier inversion formula can use integration along different lines, parallel to the real axis. Theorem: If for , and for some constants , then : f(t) = \int_^\infty \hat f(\sigma + i\tau) e^ \, d\sigma, for any . This theorem implies the Mellin inversion formula for the Laplace transformation, : f(t) = \frac 1 \int_^ F(s) e^\, ds for any , where is the Laplace transform of . The hypotheses can be weakened, as in the results of Carleman and Hunt, to being , provided that is of bounded variation in a closed neighborhood of (cf. Dirichlet-Dini theorem), the value of at is taken to be the
arithmetic mean In mathematics and statistics, the arithmetic mean ( ) or arithmetic average, or just the ''mean'' or the ''average'' (when the context is clear), is the sum of a collection of numbers divided by the count of numbers in the collection. The colle ...
of the left and right limits, and provided that the integrals are taken in the sense of Cauchy principal values. versions of these inversion formulas are also available.


Fourier transform on Euclidean space

The Fourier transform can be defined in any arbitrary number of dimensions . As with the one-dimensional case, there are many conventions. For an integrable function , this article takes the definition: :\hat(\boldsymbol) = \mathcal(f)(\boldsymbol) = \int_ f(\mathbf) e^ \, d\mathbf where and are -dimensional vectors, and is the
dot product In mathematics, the dot product or scalar productThe term ''scalar product'' means literally "product with a scalar as a result". It is also used sometimes for other symmetric bilinear forms, for example in a pseudo-Euclidean space. is an algebra ...
of the vectors. Alternatively, can be viewed as belonging to the
dual vector space In mathematics, any vector space ''V'' has a corresponding dual vector space (or just dual space for short) consisting of all linear forms on ''V'', together with the vector space structure of pointwise addition and scalar multiplication by const ...
\R^, in which case the dot product becomes the
contraction Contraction may refer to: Linguistics * Contraction (grammar), a shortened word * Poetic contraction, omission of letters for poetic reasons * Elision, omission of sounds ** Syncope (phonology), omission of sounds in a word * Synalepha, merged ...
of and , usually written as . All of the basic properties listed above hold for the -dimensional Fourier transform, as do Plancherel's and Parseval's theorem. When the function is integrable, the Fourier transform is still uniformly continuous and the
Riemann–Lebesgue lemma In mathematics, the Riemann–Lebesgue lemma, named after Bernhard Riemann and Henri Lebesgue, states that the Fourier transform or Laplace transform of an ''L''1 function vanishes at infinity. It is of importance in harmonic analysis and asymptot ...
holds.


Uncertainty principle

Generally speaking, the more concentrated is, the more spread out its Fourier transform must be. In particular, the scaling property of the Fourier transform may be seen as saying: if we squeeze a function in , its Fourier transform stretches out in . It is not possible to arbitrarily concentrate both a function and its Fourier transform. The trade-off between the compaction of a function and its Fourier transform can be formalized in the form of an
uncertainty principle In quantum mechanics, the uncertainty principle (also known as Heisenberg's uncertainty principle) is any of a variety of mathematical inequalities asserting a fundamental limit to the accuracy with which the values for certain pairs of physic ...
by viewing a function and its Fourier transform as
conjugate variables Conjugate variables are pairs of variables mathematically defined in such a way that they become Fourier transform duals, or more generally are related through Pontryagin duality. The duality relations lead naturally to an uncertainty relation— ...
with respect to the
symplectic form In mathematics, a symplectic vector space is a vector space ''V'' over a field ''F'' (for example the real numbers R) equipped with a symplectic bilinear form. A symplectic bilinear form is a mapping that is ; Bilinear: Linear in each argument s ...
on the time–frequency domain: from the point of view of the
linear canonical transformation In Hamiltonian mechanics, the linear canonical transformation (LCT) is a family of integral transforms that generalizes many classical transforms. It has 4 parameters and 1 constraint, so it is a 3-dimensional family, and can be visualized as the ac ...
, the Fourier transform is rotation by 90° in the time–frequency domain, and preserves the
symplectic form In mathematics, a symplectic vector space is a vector space ''V'' over a field ''F'' (for example the real numbers R) equipped with a symplectic bilinear form. A symplectic bilinear form is a mapping that is ; Bilinear: Linear in each argument s ...
. Suppose is an integrable and
square-integrable In mathematics, a square-integrable function, also called a quadratically integrable function or L^2 function or square-summable function, is a real number, real- or complex number, complex-valued measurable function for which the integral of the s ...
function. Without loss of generality, assume that is normalized: :\int_^\infty , f(x), ^2 \,dx=1. It follows from the
Plancherel theorem In mathematics, the Plancherel theorem (sometimes called the Parseval–Plancherel identity) is a result in harmonic analysis, proven by Michel Plancherel in 1910. It states that the integral of a function's squared modulus is equal to the inte ...
that is also normalized. The spread around may be measured by the ''dispersion about zero'' defined by :D_0(f)=\int_^\infty x^2, f(x), ^2\,dx. In probability terms, this is the
second moment In mathematics, the moments of a function are certain quantitative measures related to the shape of the function's graph. If the function represents mass density, then the zeroth moment is the total mass, the first moment (normalized by total ma ...
of about zero. The uncertainty principle states that, if is absolutely continuous and the functions and are square integrable, then :D_0(f)D_0\left(\hat\right) \geq \frac. The equality is attained only in the case :\begin f(x) &= C_1 \, e^\\ \therefore \hat(\xi) &= \sigma C_1 \, e^ \end where is arbitrary and so that is -normalized. In other words, where is a (normalized)
Gaussian function In mathematics, a Gaussian function, often simply referred to as a Gaussian, is a function of the base form f(x) = \exp (-x^2) and with parametric extension f(x) = a \exp\left( -\frac \right) for arbitrary real constants , and non-zero . It is ...
with variance , centered at zero, and its Fourier transform is a Gaussian function with variance . In fact, this inequality implies that: : \left(\int_^\infty (x-x_0)^2, f(x), ^2\,dx\right)\left(\int_^\infty(\xi-\xi_0)^2\left, \hat(\xi)\^2\,d\xi\right)\geq \frac for any , . In
quantum mechanics Quantum mechanics is a fundamental theory in physics that provides a description of the physical properties of nature at the scale of atoms and subatomic particles. It is the foundation of all quantum physics including quantum chemistry, ...
, the
momentum In Newtonian mechanics, momentum (more specifically linear momentum or translational momentum) is the product of the mass and velocity of an object. It is a vector quantity, possessing a magnitude and a direction. If is an object's mass an ...
and position
wave function A wave function in quantum physics is a mathematical description of the quantum state of an isolated quantum system. The wave function is a complex-valued probability amplitude, and the probabilities for the possible results of measurements mad ...
s are Fourier transform pairs, to within a factor of Planck's constant. With this constant properly taken into account, the inequality above becomes the statement of the
Heisenberg uncertainty principle In quantum mechanics, the uncertainty principle (also known as Heisenberg's uncertainty principle) is any of a variety of mathematical inequalities asserting a fundamental limit to the accuracy with which the values for certain pairs of physic ...
. A stronger uncertainty principle is the Hirschman uncertainty principle, which is expressed as: :H\left(\left, f\^2\right)+H\left(\left, \hat\^2\right)\ge \log\left(\frac\right) where is the
differential entropy Differential entropy (also referred to as continuous entropy) is a concept in information theory that began as an attempt by Claude Shannon to extend the idea of (Shannon) entropy, a measure of average surprisal of a random variable, to continu ...
of the
probability density function In probability theory, a probability density function (PDF), or density of a continuous random variable, is a function whose value at any given sample (or point) in the sample space (the set of possible values taken by the random variable) can ...
: :H(p) = -\int_^\infty p(x)\log\bigl(p(x)\bigr) \, dx where the logarithms may be in any base that is consistent. The equality is attained for a Gaussian, as in the previous case.


Sine and cosine transforms

Fourier's original formulation of the transform did not use complex numbers, but rather sines and cosines. Statisticians and others still use this form. An absolutely integrable function for which Fourier inversion holds can be expanded in terms of genuine frequencies (avoiding negative frequencies, which are sometimes considered hard to interpret physically) by :f(t) = \int_0^\infty \bigl( a(\lambda ) \cos( 2\pi \lambda t) + b(\lambda ) \sin( 2\pi \lambda t)\bigr) \, d\lambda. This is called an expansion as a trigonometric integral, or a Fourier integral expansion. The coefficient functions and can be found by using variants of the Fourier cosine transform and the Fourier sine transform (the normalisations are, again, not standardised): : a (\lambda) = 2\int_^\infty f(t) \cos(2\pi\lambda t) \, dt and : b (\lambda) = 2\int_^\infty f(t) \sin(2\pi\lambda t) \, dt. Older literature refers to the two transform functions, the Fourier cosine transform, , and the Fourier sine transform, . The function can be recovered from the sine and cosine transform using : f(t) = 2\int_0 ^ \int_^ f(\tau) \cos\bigl( 2\pi \lambda(\tau-t)\bigr) \, d\tau \, d\lambda. together with trigonometric identities. This is referred to as Fourier's integral formula.


Spherical harmonics

Let the set of
homogeneous Homogeneity and heterogeneity are concepts often used in the sciences and statistics relating to the uniformity of a substance or organism. A material or image that is homogeneous is uniform in composition or character (i.e. color, shape, siz ...
harmonic A harmonic is a wave with a frequency that is a positive integer multiple of the ''fundamental frequency'', the frequency of the original periodic signal, such as a sinusoidal wave. The original signal is also called the ''1st harmonic'', the ...
polynomial In mathematics, a polynomial is an expression consisting of indeterminates (also called variables) and coefficients, that involves only the operations of addition, subtraction, multiplication, and positive-integer powers of variables. An exa ...
s of degree on be denoted by . The set consists of the
solid spherical harmonics In physics and mathematics, the solid harmonics are solutions of the Laplace equation in spherical polar coordinates, assumed to be (smooth) functions \mathbb^3 \to \mathbb. There are two kinds: the ''regular solid harmonics'' R^m_\ell(\mathbf), wh ...
of degree . The solid spherical harmonics play a similar role in higher dimensions to the Hermite polynomials in dimension one. Specifically, if for some in , then . Let the set be the closure in of linear combinations of functions of the form where is in . The space is then a direct sum of the spaces and the Fourier transform maps each space to itself and is possible to characterize the action of the Fourier transform on each space . Let (with in ), then :\hat(\xi)=F_0(, \xi, )P(\xi) where :F_0(r) = 2\pi i^r^ \int_0^\infty f_0(s)J_\frac(2\pi rs)s^\frac\,ds. Here denotes the
Bessel function Bessel functions, first defined by the mathematician Daniel Bernoulli and then generalized by Friedrich Bessel, are canonical solutions of Bessel's differential equation x^2 \frac + x \frac + \left(x^2 - \alpha^2 \right)y = 0 for an arbitrary ...
of the first kind with order . When this gives a useful formula for the Fourier transform of a radial function. This is essentially the
Hankel transform In mathematics, the Hankel transform expresses any given function ''f''(''r'') as the weighted sum of an infinite number of Bessel functions of the first kind . The Bessel functions in the sum are all of the same order ν, but differ in a scaling ...
. Moreover, there is a simple recursion relating the cases and allowing to compute, e.g., the three-dimensional Fourier transform of a radial function from the one-dimensional one.


Restriction problems

In higher dimensions it becomes interesting to study ''restriction problems'' for the Fourier transform. The Fourier transform of an integrable function is continuous and the restriction of this function to any set is defined. But for a square-integrable function the Fourier transform could be a general ''class'' of square integrable functions. As such, the restriction of the Fourier transform of an function cannot be defined on sets of measure 0. It is still an active area of study to understand restriction problems in for . Surprisingly, it is possible in some cases to define the restriction of a Fourier transform to a set , provided has non-zero curvature. The case when is the unit sphere in is of particular interest. In this case the Tomas–
Stein Stein is a German, Yiddish and Norwegian word meaning "stone" and "pip" or "kernel". It stems from the same Germanic root as the English word stone. It may refer to: Places In Austria * Stein, a neighbourhood of Krems an der Donau, Lower Austr ...
restriction theorem states that the restriction of the Fourier transform to the unit sphere in is a bounded operator on provided . One notable difference between the Fourier transform in 1 dimension versus higher dimensions concerns the partial sum operator. Consider an increasing collection of measurable sets indexed by : such as balls of radius centered at the origin, or cubes of side . For a given integrable function , consider the function defined by: :f_R(x) = \int_\hat(\xi) e^\, d\xi, \quad x \in \mathbb^n. Suppose in addition that . For and , if one takes , then converges to in as tends to infinity, by the boundedness of the
Hilbert transform In mathematics and in signal processing, the Hilbert transform is a specific linear operator that takes a function, of a real variable and produces another function of a real variable . This linear operator is given by convolution with the functi ...
. Naively one may hope the same holds true for . In the case that is taken to be a cube with side length , then convergence still holds. Another natural candidate is the Euclidean ball . In order for this partial sum operator to converge, it is necessary that the multiplier for the unit ball be bounded in . For it is a celebrated theorem of
Charles Fefferman Charles Louis Fefferman (born April 18, 1949) is an American mathematician at Princeton University, where he is currently the Herbert E. Jones, Jr. '43 University Professor of Mathematics. He was awarded the Fields Medal in 1978 for his contrib ...
that the multiplier for the unit ball is never bounded unless . In fact, when , this shows that not only may fail to converge to in , but for some functions , is not even an element of .


Fourier transform on function spaces


On spaces


On

The definition of the Fourier transform by the integral formula :\hat(\xi) = \int_ f(x)e^\,dx is valid for Lebesgue integrable functions ; that is, . The Fourier transform is a
bounded operator In functional analysis and operator theory, a bounded linear operator is a linear transformation L : X \to Y between topological vector spaces (TVSs) X and Y that maps bounded subsets of X to bounded subsets of Y. If X and Y are normed vector s ...
. This follows from the observation that :\left\vert\hat(\xi)\right\vert \leq \int_ \vert f(x)\vert \,dx, which shows that its
operator norm In mathematics, the operator norm measures the "size" of certain linear operators by assigning each a real number called its . Formally, it is a norm defined on the space of bounded linear operators between two given normed vector spaces. Introdu ...
is bounded by 1. Indeed, it equals 1, which can be seen, for example, from the transform of the rect function. The image of is a subset of the space of continuous functions that tend to zero at infinity (the
Riemann–Lebesgue lemma In mathematics, the Riemann–Lebesgue lemma, named after Bernhard Riemann and Henri Lebesgue, states that the Fourier transform or Laplace transform of an ''L''1 function vanishes at infinity. It is of importance in harmonic analysis and asymptot ...
), although it is not the entire space. Indeed, there is no simple characterization of the image.


On

Since compactly supported smooth functions are integrable and dense in , the
Plancherel theorem In mathematics, the Plancherel theorem (sometimes called the Parseval–Plancherel identity) is a result in harmonic analysis, proven by Michel Plancherel in 1910. It states that the integral of a function's squared modulus is equal to the inte ...
allows us to extend the definition of the Fourier transform to general functions in by continuity arguments. The Fourier transform in is no longer given by an ordinary Lebesgue integral, although it can be computed by an
improper integral In mathematical analysis, an improper integral is the limit of a definite integral as an endpoint of the interval(s) of integration approaches either a specified real number or positive or negative infinity; or in some instances as both endpoin ...
, here meaning that for an function , :\hat(\xi) = \lim_\int_ f(x) e^\,dx where the limit is taken in the sense. (More generally, you can take a sequence of functions that are in the intersection of and and that converges to in the -norm, and define the Fourier transform of as the -limit of the Fourier transforms of these functions.) Many of the properties of the Fourier transform in carry over to , by a suitable limiting argument. Furthermore, is a
unitary operator In functional analysis, a unitary operator is a surjective bounded operator on a Hilbert space that preserves the inner product. Unitary operators are usually taken as operating ''on'' a Hilbert space, but the same notion serves to define the con ...
. For an operator to be unitary it is sufficient to show that it is bijective and preserves the inner product, so in this case these follow from the Fourier inversion theorem combined with the fact that for any we have : \int_ f(x)\mathcalg(x)\,dx = \int_ \mathcalf(x)g(x)\,dx. In particular, the image of is itself under the Fourier transform.


On other

The definition of the Fourier transform can be extended to functions in for by decomposing such functions into a fat tail part in plus a fat body part in . In each of these spaces, the Fourier transform of a function in is in , where is the
Hölder conjugate In mathematics, two real numbers p, q>1 are called conjugate indices (or Hölder conjugates) if : \frac + \frac = 1. Formally, we also define q = \infty as conjugate to p=1 and vice versa References Additional references * * {{La ...
of (by the
Hausdorff–Young inequality The Hausdorff−Young inequality is a foundational result in the mathematical field of Fourier analysis. As a statement about Fourier series, it was discovered by and extended by . It is now typically understood as a rather direct corollary of th ...
). However, except for , the image is not easily characterized. Further extensions become more technical. The Fourier transform of functions in for the range requires the study of distributions. In fact, it can be shown that there are functions in with so that the Fourier transform is not defined as a function.


Tempered distributions

One might consider enlarging the domain of the Fourier transform from by considering
generalized function In mathematics, generalized functions are objects extending the notion of functions. There is more than one recognized theory, for example the theory of distributions. Generalized functions are especially useful in making discontinuous functions ...
s, or distributions. A distribution on is a continuous linear functional on the space of compactly supported smooth functions, equipped with a suitable topology. The strategy is then to consider the action of the Fourier transform on and pass to distributions by duality. The obstruction to doing this is that the Fourier transform does not map to . In fact the Fourier transform of an element in can not vanish on an open set; see the above discussion on the uncertainty principle. The right space here is the slightly larger space of
Schwartz functions In mathematics, Schwartz space \mathcal is the function space of all functions whose derivatives are rapidly decreasing. This space has the important property that the Fourier transform is an automorphism on this space. This property enables on ...
. The Fourier transform is an automorphism on the Schwartz space, as a topological vector space, and thus induces an automorphism on its dual, the space of tempered distributions. The tempered distributions include all the integrable functions mentioned above, as well as well-behaved functions of polynomial growth and distributions of compact support. For the definition of the Fourier transform of a tempered distribution, let and be integrable functions, and let and be their Fourier transforms respectively. Then the Fourier transform obeys the following multiplication formula, :\int_\hat(x)g(x)\,dx=\int_f(x)\hat(x)\,dx. Every integrable function defines (induces) a distribution by the relation :T_f(\varphi)=\int_f(x)\varphi(x)\,dx for all Schwartz functions . So it makes sense to define Fourier transform of by :\hat_f (\varphi)= T_f\left(\hat\right) for all Schwartz functions . Extending this to all tempered distributions gives the general definition of the Fourier transform. Distributions can be differentiated and the above-mentioned compatibility of the Fourier transform with differentiation and convolution remains true for tempered distributions.


Generalizations


Fourier–Stieltjes transform

The Fourier transform of a
finite Finite is the opposite of infinite. It may refer to: * Finite number (disambiguation) * Finite set, a set whose cardinality (number of elements) is some natural number * Finite verb, a verb form that has a subject, usually being inflected or marked ...
Borel measure In mathematics, specifically in measure theory, a Borel measure on a topological space is a measure that is defined on all open sets (and thus on all Borel sets). Some authors require additional restrictions on the measure, as described below. F ...
on is given by: :\hat\mu(\xi)=\int_ e^\,d\mu. This transform continues to enjoy many of the properties of the Fourier transform of integrable functions. One notable difference is that the
Riemann–Lebesgue lemma In mathematics, the Riemann–Lebesgue lemma, named after Bernhard Riemann and Henri Lebesgue, states that the Fourier transform or Laplace transform of an ''L''1 function vanishes at infinity. It is of importance in harmonic analysis and asymptot ...
fails for measures. In the case that , then the formula above reduces to the usual definition for the Fourier transform of . In the case that is the probability distribution associated to a random variable , the Fourier–Stieltjes transform is closely related to the
characteristic function In mathematics, the term "characteristic function" can refer to any of several distinct concepts: * The indicator function of a subset, that is the function ::\mathbf_A\colon X \to \, :which for a given subset ''A'' of ''X'', has value 1 at points ...
, but the typical conventions in probability theory take instead of . In the case when the distribution has a
probability density function In probability theory, a probability density function (PDF), or density of a continuous random variable, is a function whose value at any given sample (or point) in the sample space (the set of possible values taken by the random variable) can ...
this definition reduces to the Fourier transform applied to the probability density function, again with a different choice of constants. The Fourier transform may be used to give a characterization of measures.
Bochner's theorem In mathematics, Bochner's theorem (named for Salomon Bochner) characterizes the Fourier transform of a positive finite Borel measure on the real line. More generally in harmonic analysis, Bochner's theorem asserts that under Fourier transform a c ...
characterizes which functions may arise as the Fourier–Stieltjes transform of a positive measure on the circle. Furthermore, the
Dirac delta function In mathematics, the Dirac delta distribution ( distribution), also known as the unit impulse, is a generalized function or distribution over the real numbers, whose value is zero everywhere except at zero, and whose integral over the entire ...
, although not a function, is a finite Borel measure. Its Fourier transform is a constant function (whose specific value depends upon the form of the Fourier transform used).


Kaniadakis κ-Fourier transform

The Kaniadakis κ-Fourier transform is a κ-deformation of the Fourier transform, associated with the
Kaniadakis statistics Kaniadakis statistics (also known as κ-statistics) is a generalization of Boltzmann-Gibbs statistical mechanics, based on a relativistic generalization of the classical Boltzmann-Gibbs-Shannon entropy (commonly referred to as Kaniadakis entr ...
, which is defined as: :_\kappa
(x) An emoticon (, , rarely , ), short for "emotion icon", also known simply as an emote, is a pictorial representation of a facial expression using characters—usually punctuation marks, numbers, and letters—to express a person's feelings, ...
\omega)=\int\limits_\limits^f(x)\, \,d x where z_=\frac\, \,(\kappa\,z) is a κ-number and 0 \leq , \kappa, < 1 is the entropic index linked with the Kaniadakis entropy. The κ-Fourier transform is based on the κ-Fourier series, in which the classical Fourier series and Fourier transform are particular case in the \kappa \rightarrow 0 limiting case. This transform imposes an asymptotically log-periodic behavior (or κ-deformed phase by deforminh \omega) and a damping factor following a wavelet-like behavior (\sqrt).


Locally compact abelian groups

The Fourier transform may be generalized to any locally compact abelian group. A locally compact abelian group is an
abelian group In mathematics, an abelian group, also called a commutative group, is a group in which the result of applying the group operation to two group elements does not depend on the order in which they are written. That is, the group operation is commut ...
that is at the same time a
locally compact In topology and related branches of mathematics, a topological space is called locally compact if, roughly speaking, each small portion of the space looks like a small portion of a compact space. More precisely, it is a topological space in which ev ...
Hausdorff topological space In topology and related branches of mathematics, a Hausdorff space ( , ), separated space or T2 space is a topological space where, for any two distinct points, there exist neighbourhoods of each which are disjoint from each other. Of the many ...
so that the group operation is continuous. If is a locally compact abelian group, it has a translation invariant measure , called
Haar measure In mathematical analysis, the Haar measure assigns an "invariant volume" to subsets of locally compact topological groups, consequently defining an integral for functions on those groups. This measure was introduced by Alfréd Haar in 1933, though ...
. For a locally compact abelian group , the set of irreducible, i.e. one-dimensional, unitary representations are called its
characters Character or Characters may refer to: Arts, entertainment, and media Literature * ''Character'' (novel), a 1936 Dutch novel by Ferdinand Bordewijk * ''Characters'' (Theophrastus), a classical Greek set of character sketches attributed to The ...
. With its natural group structure and the topology of pointwise convergence, the set of characters is itself a locally compact abelian group, called the ''Pontryagin dual'' of . For a function in , its Fourier transform is defined by :\hat(\xi)=\int_G \xi(x)f(x)\,d\mu\qquad\text\xi\in\hat G. The Riemann–Lebesgue lemma holds in this case; is a function vanishing at infinity on . The Fourier transform on =R/Z is an example; here is a locally compact abelian group, and the Haar measure on can be thought of as the Lebesgue measure on [0,1). Consider the representation of on the complex plane that is a 1-dimensional complex vector space. There are a group of representations (which are irreducible since is 1-dim) \ where e_(x)=e^ for x\in T. The character of such representation, that is the trace of e_(x) for each x\in T and k\in Z, is e^ itself. In the case of representation of finite group, the character table of the group are rows of vectors such that each row is the character of one irreducible representation of , and these vectors form an orthonormal basis of the space of class functions that map from to by Schur's lemma. Now the group is no longer finite but still compact, and it preserves the orthonormality of character table. Each row of the table is the function e_(x) of x\in T, and the inner product between two class functions (all functions being class functions since is abelian) f,g \in L^(T, d\mu) is defined as \langle f,g\rangle=\frac\int_f(y)\overline(y)d\mu(y) with the normalizing factor , T, =1. The sequence \ is an orthonormal basis of the space of class functions L^(T,d\mu). For any representation of a finite group , \chi_ can be expressed as the span \sum_ \left\langle \chi_,\chi_ \right\rangle \chi_ (V_ are the irreps of ), such that \left\langle \chi_,\chi_ \right\rangle = \frac\sum_\chi_(g)\overline_(g). Similarly for G=T and f\in L^(T,d\mu), f(x)=\sum_\hat(k)e_. The Pontriagin dual \hat is \(k\in Z) and for f\in L^(T,d\mu), \hat(k)=\frac\int_f(y)e^dy is its Fourier transform for e_\in \hat.


Gelfand transform

The Fourier transform is also a special case of Gelfand transform. In this particular context, it is closely related to the Pontryagin duality map defined above. Given an abelian locally compact space, locally compact Hausdorff
topological group In mathematics, topological groups are logically the combination of groups and topological spaces, i.e. they are groups and topological spaces at the same time, such that the continuity condition for the group operations connects these two str ...
, as before we consider space , defined using a Haar measure. With convolution as multiplication, is an abelian
Banach algebra In mathematics, especially functional analysis, a Banach algebra, named after Stefan Banach, is an associative algebra A over the real or complex numbers (or over a non-Archimedean complete normed field) that at the same time is also a Banach spa ...
. It also has an
involution Involution may refer to: * Involute, a construction in the differential geometry of curves * '' Agricultural Involution: The Processes of Ecological Change in Indonesia'', a 1963 study of intensification of production through increased labour inpu ...
* given by :f^*(g) = \overline. Taking the completion with respect to the largest possibly -norm gives its enveloping -algebra, called the group -algebra of . (Any -norm on is bounded by the norm, therefore their supremum exists.) Given any abelian -algebra , the Gelfand transform gives an isomorphism between and , where is the multiplicative linear functionals, i.e. one-dimensional representations, on with the weak-* topology. The map is simply given by :a \mapsto \bigl( \varphi \mapsto \varphi(a) \bigr) It turns out that the multiplicative linear functionals of , after suitable identification, are exactly the characters of , and the Gelfand transform, when restricted to the dense subset is the Fourier–Pontryagin transform.


Compact non-abelian groups

The Fourier transform can also be defined for functions on a non-abelian group, provided that the group is
compact Compact as used in politics may refer broadly to a pact or treaty; in more specific cases it may refer to: * Interstate compact * Blood compact, an ancient ritual of the Philippines * Compact government, a type of colonial rule utilized in British ...
. Removing the assumption that the underlying group is abelian, irreducible unitary representations need not always be one-dimensional. This means the Fourier transform on a non-abelian group takes values as Hilbert space operators. The Fourier transform on compact groups is a major tool in
representation theory Representation theory is a branch of mathematics that studies abstract algebraic structures by ''representing'' their elements as linear transformations of vector spaces, and studies modules over these abstract algebraic structures. In essen ...
and
non-commutative harmonic analysis In mathematics, noncommutative harmonic analysis is the field in which results from Fourier analysis are extended to topological groups that are not commutative. Since locally compact abelian groups have a well-understood theory, Pontryagin duality ...
. Let be a compact Hausdorff
topological group In mathematics, topological groups are logically the combination of groups and topological spaces, i.e. they are groups and topological spaces at the same time, such that the continuity condition for the group operations connects these two str ...
. Let denote the collection of all isomorphism classes of finite-dimensional irreducible
unitary representation In mathematics, a unitary representation of a group ''G'' is a linear representation π of ''G'' on a complex Hilbert space ''V'' such that π(''g'') is a unitary operator for every ''g'' ∈ ''G''. The general theory is well-developed in case ''G'' ...
s, along with a definite choice of representation on the
Hilbert space In mathematics, Hilbert spaces (named after David Hilbert) allow generalizing the methods of linear algebra and calculus from (finite-dimensional) Euclidean vector spaces to spaces that may be infinite-dimensional. Hilbert spaces arise natural ...
of finite dimension for each . If is a finite
Borel measure In mathematics, specifically in measure theory, a Borel measure on a topological space is a measure that is defined on all open sets (and thus on all Borel sets). Some authors require additional restrictions on the measure, as described below. F ...
on , then the Fourier–Stieltjes transform of is the operator on defined by :\left\langle \hat\xi,\eta\right\rangle_ = \int_G \left\langle \overline^_g\xi,\eta\right\rangle\,d\mu(g) where is the complex-conjugate representation of acting on . If is
absolutely continuous In calculus, absolute continuity is a smoothness property of functions that is stronger than continuity and uniform continuity. The notion of absolute continuity allows one to obtain generalizations of the relationship between the two central oper ...
with respect to the left-invariant probability measure on , represented as :d\mu = f \, d\lambda for some , one identifies the Fourier transform of with the Fourier–Stieltjes transform of . The mapping :\mu\mapsto\hat defines an isomorphism between the
Banach space In mathematics, more specifically in functional analysis, a Banach space (pronounced ) is a complete normed vector space. Thus, a Banach space is a vector space with a metric that allows the computation of vector length and distance between vector ...
of finite Borel measures (see
rca space In mathematics, the ba space ba(\Sigma) of an algebra of sets \Sigma is the Banach space consisting of all bounded and finitely additive signed measures on \Sigma. The norm is defined as the variation, that is \, \nu\, =, \nu, (X). If Σ ...
) and a closed subspace of the Banach space consisting of all sequences indexed by of (bounded) linear operators for which the norm :\, E\, = \sup_\left\, E_\sigma\right\, is finite. The "
convolution theorem In mathematics, the convolution theorem states that under suitable conditions the Fourier transform of a convolution of two functions (or signals) is the pointwise product of their Fourier transforms. More generally, convolution in one domain (e.g. ...
" asserts that, furthermore, this isomorphism of Banach spaces is in fact an isometric isomorphism of
C*-algebra In mathematics, specifically in functional analysis, a C∗-algebra (pronounced "C-star") is a Banach algebra together with an involution satisfying the properties of the adjoint. A particular case is that of a complex algebra ''A'' of continuous ...
s into a subspace of . Multiplication on is given by
convolution In mathematics (in particular, functional analysis), convolution is a operation (mathematics), mathematical operation on two function (mathematics), functions ( and ) that produces a third function (f*g) that expresses how the shape of one is ...
of measures and the involution * defined by :f^*(g) = \overline, and has a natural -algebra structure as Hilbert space operators. The
Peter–Weyl theorem In mathematics, the Peter–Weyl theorem is a basic result in the theory of harmonic analysis, applying to topological groups that are compact, but are not necessarily abelian. It was initially proved by Hermann Weyl, with his student Fritz Peter, ...
holds, and a version of the Fourier inversion formula (
Plancherel's theorem In mathematics, the Plancherel theorem (sometimes called the Parseval–Plancherel identity) is a result in harmonic analysis, proven by Michel Plancherel in 1910. It states that the integral of a function's squared modulus is equal to the integr ...
) follows: if , then :f(g) = \sum_ d_\sigma \operatorname\left(\hat(\sigma)U^_g\right) where the summation is understood as convergent in the sense. The generalization of the Fourier transform to the noncommutative situation has also in part contributed to the development of
noncommutative geometry Noncommutative geometry (NCG) is a branch of mathematics concerned with a geometric approach to noncommutative algebras, and with the construction of ''spaces'' that are locally presented by noncommutative algebras of functions (possibly in some ge ...
. In this context, a categorical generalization of the Fourier transform to noncommutative groups is
Tannaka–Krein duality In mathematics, Tannaka–Krein duality theory concerns the interaction of a compact topological group and its category of linear representations. It is a natural extension of Pontryagin duality, between compact and discrete commutative topologic ...
, which replaces the group of characters with the category of representations. However, this loses the connection with harmonic functions.


Alternatives

In
signal processing Signal processing is an electrical engineering subfield that focuses on analyzing, modifying and synthesizing ''signals'', such as audio signal processing, sound, image processing, images, and scientific measurements. Signal processing techniq ...
terms, a function (of time) is a representation of a signal with perfect ''time resolution'', but no frequency information, while the Fourier transform has perfect ''frequency resolution'', but no time information: the magnitude of the Fourier transform at a point is how much frequency content there is, but location is only given by phase (argument of the Fourier transform at a point), and
standing wave In physics, a standing wave, also known as a stationary wave, is a wave that oscillates in time but whose peak amplitude profile does not move in space. The peak amplitude of the wave oscillations at any point in space is constant with respect ...
s are not localized in time – a sine wave continues out to infinity, without decaying. This limits the usefulness of the Fourier transform for analyzing signals that are localized in time, notably
transients Transience or transient may refer to: Music * ''Transient'' (album), a 2004 album by Gaelle * ''Transience'' (Steven Wilson album), 2015 * Transience (Wreckless Eric album) Science and engineering * Transient state, when a process variable or ...
, or any signal of finite extent. As alternatives to the Fourier transform, in
time–frequency analysis In signal processing, time–frequency analysis comprises those techniques that study a signal in both the time and frequency domains ''simultaneously,'' using various time–frequency representations. Rather than viewing a 1-dimensional signal (a ...
, one uses time–frequency transforms or time–frequency distributions to represent signals in a form that has some time information and some frequency information – by the uncertainty principle, there is a trade-off between these. These can be generalizations of the Fourier transform, such as the
short-time Fourier transform The short-time Fourier transform (STFT), is a Fourier-related transform used to determine the sinusoidal frequency and phase content of local sections of a signal as it changes over time. In practice, the procedure for computing STFTs is to divid ...
or
fractional Fourier transform In mathematics, in the area of harmonic analysis, the fractional Fourier transform (FRFT) is a family of linear transformations generalizing the Fourier transform. It can be thought of as the Fourier transform to the ''n''-th power, where ''n'' n ...
, or other functions to represent signals, as in
wavelet transform In mathematics, a wavelet series is a representation of a square-integrable (real number, real- or complex number, complex-valued) function (mathematics), function by a certain orthonormal series (mathematics), series generated by a wavelet. This ...
s and
chirplet transform In signal processing, the chirplet transform is an inner product of an input signal with a family of analysis primitives called chirplets.S. Mann and S. Haykin,The Chirplet transform: A generalization of Gabor's logon transform, ''Proc. Vision Int ...
s, with the wavelet analog of the (continuous) Fourier transform being the
continuous wavelet transform Continuity or continuous may refer to: Mathematics * Continuity (mathematics), the opposing concept to discreteness; common examples include ** Continuous probability distribution or random variable in probability and statistics ** Continuous g ...
.


Applications

Linear operations performed in one domain (time or frequency) have corresponding operations in the other domain, which are sometimes easier to perform. The operation of differentiation in the time domain corresponds to multiplication by the frequency,Up to an imaginary constant factor whose magnitude depends on what Fourier transform convention is used. so some
differential equation In mathematics, a differential equation is an equation that relates one or more unknown functions and their derivatives. In applications, the functions generally represent physical quantities, the derivatives represent their rates of change, an ...
s are easier to analyze in the frequency domain. Also,
convolution In mathematics (in particular, functional analysis), convolution is a operation (mathematics), mathematical operation on two function (mathematics), functions ( and ) that produces a third function (f*g) that expresses how the shape of one is ...
in the time domain corresponds to ordinary multiplication in the frequency domain (see
Convolution theorem In mathematics, the convolution theorem states that under suitable conditions the Fourier transform of a convolution of two functions (or signals) is the pointwise product of their Fourier transforms. More generally, convolution in one domain (e.g. ...
). After performing the desired operations, transformation of the result can be made back to the time domain.
Harmonic analysis Harmonic analysis is a branch of mathematics concerned with the representation of Function (mathematics), functions or signals as the Superposition principle, superposition of basic waves, and the study of and generalization of the notions of Fo ...
is the systematic study of the relationship between the frequency and time domains, including the kinds of functions or operations that are "simpler" in one or the other, and has deep connections to many areas of modern mathematics.


Analysis of differential equations

Perhaps the most important use of the Fourier transformation is to solve
partial differential equation In mathematics, a partial differential equation (PDE) is an equation which imposes relations between the various partial derivatives of a Multivariable calculus, multivariable function. The function is often thought of as an "unknown" to be sol ...
s. Many of the equations of the mathematical physics of the nineteenth century can be treated this way. Fourier studied the heat equation, which in one dimension and in dimensionless units is :\frac =\frac. The example we will give, a slightly more difficult one, is the wave equation in one dimension, :\frac=\frac. As usual, the problem is not to find a solution: there are infinitely many. The problem is that of the so-called "boundary problem": find a solution which satisfies the "boundary conditions" :y(x,0) = f(x) , \qquad \frac= g(x). Here, and are given functions. For the heat equation, only one boundary condition can be required (usually the first one). But for the wave equation, there are still infinitely many solutions which satisfy the first boundary condition. But when one imposes both conditions, there is only one possible solution. It is easier to find the Fourier transform of the solution than to find the solution directly. This is because the Fourier transformation takes differentiation into multiplication by the Fourier-dual variable, and so a partial differential equation applied to the original function is transformed into multiplication by polynomial functions of the dual variables applied to the transformed function. After is determined, we can apply the inverse Fourier transformation to find . Fourier's method is as follows. First, note that any function of the forms : \cos\bigl(2\pi\xi(x\pm t)\bigr) \mbox \sin\bigl(2\pi\xi(x \pm t)\bigr) satisfies the wave equation. These are called the elementary solutions. Second, note that therefore any integral \begin y(x,t) &= \int_^ d\xi & a_+(\xi)\cos\bigl(2\pi\xi(x +t)\bigr) + a_-(\xi)\cos\bigl(2\pi\xi(x -t)\bigr)+ \\ & & b_+(\xi)\sin\bigl(2\pi\xi(x +t)\bigr) + b_-(\xi)\sin\left(2\pi\xi(x -t)\right) \end satisfies the wave equation for arbitrary . This integral may be interpreted as a continuous linear combination of solutions for the linear equation. Now this resembles the formula for the Fourier synthesis of a function. In fact, this is the real inverse Fourier transform of and in the variable . The third step is to examine how to find the specific unknown coefficient functions and that will lead to satisfying the boundary conditions. We are interested in the values of these solutions at . So we will set . Assuming that the conditions needed for Fourier inversion are satisfied, we can then find the Fourier sine and cosine transforms (in the variable ) of both sides and obtain : 2\int_^\infty y(x,0) \cos(2\pi\xi x) \, dx = a_++a_- and :2\int_^\infty y(x,0) \sin(2\pi\xi x) \, dx = b_++b_-. Similarly, taking the derivative of with respect to and then applying the Fourier sine and cosine transformations yields : 2\int_^ \frac \sin (2\pi\xi x) \, dx = (2\pi\xi)\left(-a_++a_-\right) and :2\int_^\infty \frac \cos (2\pi\xi x) \, dx = (2\pi\xi)\left(b_+-b_-\right). These are four linear equations for the four unknowns and , in terms of the Fourier sine and cosine transforms of the boundary conditions, which are easily solved by elementary algebra, provided that these transforms can be found. In summary, we chose a set of elementary solutions, parametrized by , of which the general solution would be a (continuous) linear combination in the form of an integral over the parameter . But this integral was in the form of a Fourier integral. The next step was to express the boundary conditions in terms of these integrals, and set them equal to the given functions and . But these expressions also took the form of a Fourier integral because of the properties of the Fourier transform of a derivative. The last step was to exploit Fourier inversion by applying the Fourier transformation to both sides, thus obtaining expressions for the coefficient functions and in terms of the given boundary conditions and . From a higher point of view, Fourier's procedure can be reformulated more conceptually. Since there are two variables, we will use the Fourier transformation in both and rather than operate as Fourier did, who only transformed in the spatial variables. Note that must be considered in the sense of a distribution since is not going to be : as a wave, it will persist through time and thus is not a transient phenomenon. But it will be bounded and so its Fourier transform can be defined as a distribution. The operational properties of the Fourier transformation that are relevant to this equation are that it takes differentiation in to multiplication by and differentiation with respect to to multiplication by where is the frequency. Then the wave equation becomes an algebraic equation in : :\xi^2 \hat y (\xi, f) = f^2 \hat y (\xi, f). This is equivalent to requiring unless . Right away, this explains why the choice of elementary solutions we made earlier worked so well: obviously will be solutions. Applying Fourier inversion to these delta functions, we obtain the elementary solutions we picked earlier. But from the higher point of view, one does not pick elementary solutions, but rather considers the space of all distributions which are supported on the (degenerate) conic . We may as well consider the distributions supported on the conic that are given by distributions of one variable on the line plus distributions on the line as follows: if is any test function, :\iint \hat y \phi(\xi,f) \, d\xi \, df = \int s_+ \phi(\xi,\xi) \, d\xi + \int s_- \phi(\xi,-\xi) \, d\xi, where , and , are distributions of one variable. Then Fourier inversion gives, for the boundary conditions, something very similar to what we had more concretely above (put , which is clearly of polynomial growth): : y(x,0) = \int\bigl\ e^ \, d\xi and : \frac = \int\bigl\ 2\pi i \xi e^ \, d\xi. Now, as before, applying the one-variable Fourier transformation in the variable to these functions of yields two equations in the two unknown distributions (which can be taken to be ordinary functions if the boundary conditions are or ). From a calculational point of view, the drawback of course is that one must first calculate the Fourier transforms of the boundary conditions, then assemble the solution from these, and then calculate an inverse Fourier transform. Closed form formulas are rare, except when there is some geometric symmetry that can be exploited, and the numerical calculations are difficult because of the oscillatory nature of the integrals, which makes convergence slow and hard to estimate. For practical calculations, other methods are often used. The twentieth century has seen the extension of these methods to all linear partial differential equations with polynomial coefficients, and by extending the notion of Fourier transformation to include Fourier integral operators, some non-linear equations as well.


Fourier transform spectroscopy

The Fourier transform is also used in
nuclear magnetic resonance Nuclear magnetic resonance (NMR) is a physical phenomenon in which nuclei in a strong constant magnetic field are perturbed by a weak oscillating magnetic field (in the near field) and respond by producing an electromagnetic signal with a ...
(NMR) and in other kinds of
spectroscopy Spectroscopy is the field of study that measures and interprets the electromagnetic spectra that result from the interaction between electromagnetic radiation and matter as a function of the wavelength or frequency of the radiation. Matter wa ...
, e.g. infrared ( FTIR). In NMR an exponentially shaped free induction decay (FID) signal is acquired in the time domain and Fourier-transformed to a Lorentzian line-shape in the frequency domain. The Fourier transform is also used in
magnetic resonance imaging Magnetic resonance imaging (MRI) is a medical imaging technique used in radiology to form pictures of the anatomy and the physiological processes of the body. MRI scanners use strong magnetic fields, magnetic field gradients, and radio wave ...
(MRI) and
mass spectrometry Mass spectrometry (MS) is an analytical technique that is used to measure the mass-to-charge ratio of ions. The results are presented as a ''mass spectrum'', a plot of intensity as a function of the mass-to-charge ratio. Mass spectrometry is use ...
.


Quantum mechanics

The Fourier transform is useful in
quantum mechanics Quantum mechanics is a fundamental theory in physics that provides a description of the physical properties of nature at the scale of atoms and subatomic particles. It is the foundation of all quantum physics including quantum chemistry, ...
in at least two different ways. To begin with, the basic conceptual structure of quantum mechanics postulates the existence of pairs of
complementary variables In physics, complementarity is a conceptual aspect of quantum mechanics that Niels Bohr regarded as an essential feature of the theory. The complementarity principle holds that objects have certain pairs of complementary properties which cannot al ...
, connected by the
Heisenberg uncertainty principle In quantum mechanics, the uncertainty principle (also known as Heisenberg's uncertainty principle) is any of a variety of mathematical inequalities asserting a fundamental limit to the accuracy with which the values for certain pairs of physic ...
. For example, in one dimension, the spatial variable of, say, a particle, can only be measured by the quantum mechanical "
position operator In quantum mechanics, the position operator is the operator that corresponds to the position observable of a particle. When the position operator is considered with a wide enough domain (e.g. the space of tempered distributions), its eigenvalues ...
" at the cost of losing information about the momentum of the particle. Therefore, the physical state of the particle can either be described by a function, called "the wave function", of or by a function of but not by a function of both variables. The variable is called the conjugate variable to . In classical mechanics, the physical state of a particle (existing in one dimension, for simplicity of exposition) would be given by assigning definite values to both and simultaneously. Thus, the set of all possible physical states is the two-dimensional real vector space with a -axis and a -axis called the
phase space In dynamical system theory, a phase space is a space in which all possible states of a system are represented, with each possible state corresponding to one unique point in the phase space. For mechanical systems, the phase space usually ...
. In contrast, quantum mechanics chooses a polarisation of this space in the sense that it picks a subspace of one-half the dimension, for example, the -axis alone, but instead of considering only points, takes the set of all complex-valued "wave functions" on this axis. Nevertheless, choosing the -axis is an equally valid polarisation, yielding a different representation of the set of possible physical states of the particle which is related to the first representation by the Fourier transformation :\phi(p) = \int \psi (q) e^\, dq. Physically realisable states are , and so by the
Plancherel theorem In mathematics, the Plancherel theorem (sometimes called the Parseval–Plancherel identity) is a result in harmonic analysis, proven by Michel Plancherel in 1910. It states that the integral of a function's squared modulus is equal to the inte ...
, their Fourier transforms are also . (Note that since is in units of distance and is in units of momentum, the presence of Planck's constant in the exponent makes the exponent
dimensionless A dimensionless quantity (also known as a bare quantity, pure quantity, or scalar quantity as well as quantity of dimension one) is a quantity to which no physical dimension is assigned, with a corresponding SI unit of measurement of one (or 1) ...
, as it should be.) Therefore, the Fourier transform can be used to pass from one way of representing the state of the particle, by a wave function of position, to another way of representing the state of the particle: by a wave function of momentum. Infinitely many different polarisations are possible, and all are equally valid. Being able to transform states from one representation to another by the Fourier transform is not only convenient but also the underlying reason of the Heisenberg
uncertainty principle In quantum mechanics, the uncertainty principle (also known as Heisenberg's uncertainty principle) is any of a variety of mathematical inequalities asserting a fundamental limit to the accuracy with which the values for certain pairs of physic ...
. The other use of the Fourier transform in both quantum mechanics and
quantum field theory In theoretical physics, quantum field theory (QFT) is a theoretical framework that combines classical field theory, special relativity, and quantum mechanics. QFT is used in particle physics to construct physical models of subatomic particles and ...
is to solve the applicable wave equation. In non-relativistic quantum mechanics, Schrödinger's equation for a time-varying wave function in one-dimension, not subject to external forces, is :-\frac \psi(x,t) = i \frac h \frac \psi(x,t). This is the same as the heat equation except for the presence of the imaginary unit . Fourier methods can be used to solve this equation. In the presence of a potential, given by the potential energy function , the equation becomes :-\frac \psi(x,t) + V(x)\psi(x,t) = i \frac h \frac \psi(x,t). The "elementary solutions", as we referred to them above, are the so-called "stationary states" of the particle, and Fourier's algorithm, as described above, can still be used to solve the boundary value problem of the future evolution of given its values for . Neither of these approaches is of much practical use in quantum mechanics. Boundary value problems and the time-evolution of the wave function is not of much practical interest: it is the stationary states that are most important. In relativistic quantum mechanics, Schrödinger's equation becomes a wave equation as was usual in classical physics, except that complex-valued waves are considered. A simple example, in the absence of interactions with other particles or fields, is the free one-dimensional Klein–Gordon–Schrödinger–Fock equation, this time in dimensionless units, :\left (\frac +1 \right) \psi(x,t) = \frac \psi(x,t). This is, from the mathematical point of view, the same as the wave equation of classical physics solved above (but with a complex-valued wave, which makes no difference in the methods). This is of great use in quantum field theory: each separate Fourier component of a wave can be treated as a separate harmonic oscillator and then quantized, a procedure known as "second quantization". Fourier methods have been adapted to also deal with non-trivial interactions. Finally, the
number operator In quantum mechanics, for systems where the total number of particles may not be preserved, the number operator is the observable that counts the number of particles. The number operator acts on Fock space. Let :, \Psi\rangle_\nu=, \phi_1,\phi_2 ...
of the
quantum harmonic oscillator 量子調和振動子 は、 古典調和振動子 の 量子力学 類似物です。任意の滑らかな ポテンシャル は通常、安定した 平衡点 の近くで 調和ポテンシャル として近似できるため、最 ...
can be interpreted, for example via the Mehler kernel, as the
generator Generator may refer to: * Signal generator, electronic devices that generate repeating or non-repeating electronic signals * Electric generator, a device that converts mechanical energy to electrical energy. * Generator (circuit theory), an eleme ...
of the
Fourier transform A Fourier transform (FT) is a mathematical transform that decomposes functions into frequency components, which are represented by the output of the transform as a function of frequency. Most commonly functions of time or space are transformed, ...
\mathcal.


Signal processing

The Fourier transform is used for the spectral analysis of time-series. The subject of statistical signal processing does not, however, usually apply the Fourier transformation to the signal itself. Even if a real signal is indeed transient, it has been found in practice advisable to model a signal by a function (or, alternatively, a stochastic process) which is stationary in the sense that its characteristic properties are constant over all time. The Fourier transform of such a function does not exist in the usual sense, and it has been found more useful for the analysis of signals to instead take the Fourier transform of its autocorrelation function. The autocorrelation function of a function is defined by :R_f (\tau) = \lim_ \frac \int_^T f(t) f(t+\tau) \, dt. This function is a function of the time-lag elapsing between the values of to be correlated. For most functions that occur in practice, is a bounded even function of the time-lag and for typical noisy signals it turns out to be uniformly continuous with a maximum at . The autocorrelation function, more properly called the autocovariance function unless it is normalized in some appropriate fashion, measures the strength of the correlation between the values of separated by a time lag. This is a way of searching for the correlation of with its own past. It is useful even for other statistical tasks besides the analysis of signals. For example, if represents the temperature at time , one expects a strong correlation with the temperature at a time lag of 24 hours. It possesses a Fourier transform, : P_f(\xi) = \int_^\infty R_f (\tau) e^ \, d\tau. This Fourier transform is called the
power spectral density The power spectrum S_(f) of a time series x(t) describes the distribution of power into frequency components composing that signal. According to Fourier analysis, any physical signal can be decomposed into a number of discrete frequencies, o ...
function of . (Unless all periodic components are first filtered out from , this integral will diverge, but it is easy to filter out such periodicities.) The power spectrum, as indicated by this density function , measures the amount of variance contributed to the data by the frequency . In electrical signals, the variance is proportional to the average power (energy per unit time), and so the power spectrum describes how much the different frequencies contribute to the average power of the signal. This process is called the spectral analysis of time-series and is analogous to the usual analysis of variance of data that is not a time-series (
ANOVA Analysis of variance (ANOVA) is a collection of statistical models and their associated estimation procedures (such as the "variation" among and between groups) used to analyze the differences among means. ANOVA was developed by the statistician ...
). Knowledge of which frequencies are "important" in this sense is crucial for the proper design of filters and for the proper evaluation of measuring apparatuses. It can also be useful for the scientific analysis of the phenomena responsible for producing the data. The power spectrum of a signal can also be approximately measured directly by measuring the average power that remains in a signal after all the frequencies outside a narrow band have been filtered out. Spectral analysis is carried out for visual signals as well. The power spectrum ignores all phase relations, which is good enough for many purposes, but for video signals other types of spectral analysis must also be employed, still using the Fourier transform as a tool.


Other notations

Other common notations for include: :\tilde(\xi),\ F(\xi),\ \mathcal\left(f\right)(\xi),\ \left(\mathcalf\right)(\xi),\ \mathcal(f),\ \mathcal\,\ \mathcal \bigl(f(t)\bigr),\ \mathcal \bigl\. Denoting the Fourier transform by a capital letter corresponding to the letter of function being transformed (such as and ) is especially common in the sciences and engineering. In electronics, omega () is often used instead of due to its interpretation as angular frequency, sometimes it is written as , where is the
imaginary unit The imaginary unit or unit imaginary number () is a solution to the quadratic equation x^2+1=0. Although there is no real number with this property, can be used to extend the real numbers to what are called complex numbers, using addition an ...
, to indicate its relationship with the
Laplace transform In mathematics, the Laplace transform, named after its discoverer Pierre-Simon Laplace (), is an integral transform In mathematics, an integral transform maps a function from its original function space into another function space via integra ...
, and sometimes it is written informally as in order to use ordinary frequency. In some contexts such as particle physics, the same symbol f may be used for both for a function as well as it Fourier transform, with the two only distinguished by their
argument An argument is a statement or group of statements called premises intended to determine the degree of truth or acceptability of another statement called conclusion. Arguments can be studied from three main perspectives: the logical, the dialectic ...
: f(k_1 + k_2) would refer to the Fourier transform because of the momentum argument, while f(x_0 + \pi \vec r) would refer to the original function because of the positional argument. Although tildes may be used as in \tilde to indicate Fourier transforms, tildes may also be used to indicate a modification of a quantity with a more
Lorentz invariant In a relativistic theory of physics, a Lorentz scalar is an expression, formed from items of the theory, which evaluates to a scalar, invariant under any Lorentz transformation. A Lorentz scalar may be generated from e.g., the scalar product of v ...
form, such as \tilde = \frac, so care must be taken. Similarly, \hat f often denotes the
Hilbert transform In mathematics and in signal processing, the Hilbert transform is a specific linear operator that takes a function, of a real variable and produces another function of a real variable . This linear operator is given by convolution with the functi ...
of f. The interpretation of the complex function may be aided by expressing it in
polar coordinate In mathematics, the polar coordinate system is a two-dimensional coordinate system in which each point on a plane is determined by a distance from a reference point and an angle from a reference direction. The reference point (analogous to the or ...
form :\hat f(\xi) = A(\xi) e^ in terms of the two real functions and where: :A(\xi) = \left, \hat f(\xi)\, is the
amplitude The amplitude of a periodic variable is a measure of its change in a single period (such as time or spatial period). The amplitude of a non-periodic signal is its magnitude compared with a reference value. There are various definitions of am ...
and :\varphi (\xi) = \arg \left( \hat f(\xi) \right), is the
phase Phase or phases may refer to: Science *State of matter, or phase, one of the distinct forms in which matter can exist *Phase (matter), a region of space throughout which all physical properties are essentially uniform * Phase space, a mathematic ...
(see arg function). Then the inverse transform can be written: :f(x) = \int _^\infty A(\xi)\ e^\,d\xi, which is a recombination of all the frequency components of . Each component is a complex
sinusoid A sine wave, sinusoidal wave, or just sinusoid is a mathematical curve defined in terms of the ''sine'' trigonometric function, of which it is the graph. It is a type of continuous wave and also a smooth periodic function. It occurs often in ma ...
of the form whose amplitude is and whose initial phase angle (at ) is . The Fourier transform may be thought of as a mapping on function spaces. This mapping is here denoted and is used to denote the Fourier transform of the function . This mapping is linear, which means that can also be seen as a linear transformation on the function space and implies that the standard notation in linear algebra of applying a linear transformation to a vector (here the function ) can be used to write instead of . Since the result of applying the Fourier transform is again a function, we can be interested in the value of this function evaluated at the value for its variable, and this is denoted either as or as . Notice that in the former case, it is implicitly understood that is applied first to and then the resulting function is evaluated at , not the other way around. In mathematics and various applied sciences, it is often necessary to distinguish between a function and the value of when its variable equals , denoted . This means that a notation like formally can be interpreted as the Fourier transform of the values of at . Despite this flaw, the previous notation appears frequently, often when a particular function or a function of a particular variable is to be transformed. For example, :\mathcal F\bigl( \operatorname(x) \bigr) = \operatorname(\xi) is sometimes used to express that the Fourier transform of a
rectangular function The rectangular function (also known as the rectangle function, rect function, Pi function, Heaviside Pi function, gate function, unit pulse, or the normalized boxcar function) is defined as \operatorname(t) = \Pi(t) = \left\{\begin{array}{r ...
is a
sinc function In mathematics, physics and engineering, the sinc function, denoted by , has two forms, normalized and unnormalized.. In mathematics, the historical unnormalized sinc function is defined for by \operatornamex = \frac. Alternatively, the u ...
, or :\mathcal F\bigl(f(x + x_0)\bigr) = \mathcal F\bigl(f(x)\bigr)\, e^ is used to express the shift property of the Fourier transform. Notice, that the last example is only correct under the assumption that the transformed function is a function of , not of .


Other conventions

The Fourier transform can also be written in terms of
angular frequency In physics, angular frequency "''ω''" (also referred to by the terms angular speed, circular frequency, orbital frequency, radian frequency, and pulsatance) is a scalar measure of rotation rate. It refers to the angular displacement per unit tim ...
: :\omega = 2\pi \xi, whose units are
radian The radian, denoted by the symbol rad, is the unit of angle in the International System of Units (SI) and is the standard unit of angular measure used in many areas of mathematics. The unit was formerly an SI supplementary unit (before that c ...
s per second. The substitution into the formulas above produces this convention: :\hat(\omega) = \int_^ f(x)\cdot e^\, dx = \hat\left(\tfrac\right). Under this convention, the inverse transform becomes: :f(x) = \frac \int_^ \hat(\omega)\cdot e^\, d\omega. Unlike the convention followed in this article, when the Fourier transform is defined this way, it is no longer a
unitary transformation In mathematics, a unitary transformation is a transformation that preserves the inner product: the inner product of two vectors before the transformation is equal to their inner product after the transformation. Formal definition More precisely, ...
on . There is also less symmetry between the formulas for the Fourier transform and its inverse. Another convention is to split the factor of evenly between the Fourier transform and its inverse, which leads to definitions: :\begin \hat(\omega) &= \frac \int_^ f(x)\cdot e^\, dx = \frac\cdot \hat f\left(\tfrac\right), \\ f(x) &= \frac \int_^ \hat(\omega)\cdot e^\, d\omega. \end Under this convention, the Fourier transform is again a unitary transformation on . It also restores the symmetry between the Fourier transform and its inverse. Variations of all three conventions can be created by conjugating the complex-exponential
kernel Kernel may refer to: Computing * Kernel (operating system), the central component of most operating systems * Kernel (image processing), a matrix used for image convolution * Compute kernel, in GPGPU programming * Kernel method, in machine learnin ...
of both the forward and the reverse transform. The signs must be opposites. Other than that, the choice is (again) a matter of convention. As discussed above, the
characteristic function In mathematics, the term "characteristic function" can refer to any of several distinct concepts: * The indicator function of a subset, that is the function ::\mathbf_A\colon X \to \, :which for a given subset ''A'' of ''X'', has value 1 at points ...
of a random variable is the same as the Fourier–Stieltjes transform of its distribution measure, but in this context it is typical to take a different convention for the constants. Typically characteristic function is defined :E\left(e^\right)=\int e^ \, d\mu_X(x). As in the case of the "non-unitary angular frequency" convention above, the factor of 2 appears in neither the normalizing constant nor the exponent. Unlike any of the conventions appearing above, this convention takes the opposite sign in the exponent.


Computation methods

The appropriate computation method largely depends how the original mathematical function is represented and the desired form of the output function. Since the fundamental definition of a Fourier transform is an integral, functions that can be expressed as
closed-form expression In mathematics, a closed-form expression is a mathematical expression that uses a finite number of standard operations. It may contain constants, variables, certain well-known operations (e.g., + − × ÷), and functions (e.g., ''n''th roo ...
s are commonly computed by working the integral analytically to yield a closed-form expression in the Fourier transform conjugate variable as the result. This is the method used to generate tables of Fourier transforms,. including those found in the table below ( Fourier transform#Tables of important Fourier transforms). Many computer algebra systems such as
Matlab MATLAB (an abbreviation of "MATrix LABoratory") is a proprietary multi-paradigm programming language and numeric computing environment developed by MathWorks. MATLAB allows matrix manipulations, plotting of functions and data, implementation ...
and
Mathematica Wolfram Mathematica is a software system with built-in libraries for several areas of technical computing that allow machine learning, statistics, symbolic computation, data manipulation, network analysis, time series analysis, NLP, optimizat ...
that are capable of
symbolic integration In calculus, symbolic integration is the problem of finding a formula for the antiderivative, or ''indefinite integral'', of a given function ''f''(''x''), i.e. to find a differentiable function ''F''(''x'') such that :\frac = f(x). This is also ...
are capable of computing Fourier transforms analytically. For example, to compute the Fourier transform of one might enter the command into
Wolfram Alpha WolframAlpha ( ) is an answer engine developed by Wolfram Research. It answers factual queries by computing answers from externally sourced data. WolframAlpha was released on May 18, 2009 and is based on Wolfram's earlier product Wolfram Mathe ...
.The direct command would also work for Wolfram Alpha.


Numerical integration of closed-form functions

If the input function is in closed-form and the desired output function is a series of ordered pairs (for example a table of values from which a graph can be generated) over a specified domain, then the Fourier transform can be generated by
numerical integration In analysis, numerical integration comprises a broad family of algorithms for calculating the numerical value of a definite integral, and by extension, the term is also sometimes used to describe the numerical solution of differential equations ...
at each value of the Fourier conjugate variable (frequency, for example) for which a value of the output variable is desired. Note that this method requires computing a separate numerical integration for each value of frequency for which a value of the Fourier transform is desired. The numerical integration approach works on a much broader class of functions than the analytic approach, because it yields results for functions that do not have closed form Fourier transform integrals.


Numerical integration of a series of ordered pairs

If the input function is a series of ordered pairs (for example, a time series from measuring an output variable repeatedly over a time interval) then the output function must also be a series of ordered pairs (for example, a complex number vs. frequency over a specified domain of frequencies), unless certain assumptions and approximations are made allowing the output function to be approximated by a closed-form expression. In the general case where the available input series of ordered pairs are assumed be samples representing a continuous function over an interval (amplitude vs. time, for example), the series of ordered pairs representing the desired output function can be obtained by numerical integration of the input data over the available interval at each value of the Fourier conjugate variable (frequency, for example) for which the value of the Fourier transform is desired. Explicit numerical integration over the ordered pairs can yield the Fourier transform output value for any desired value of the conjugate Fourier transform variable (frequency, for example), so that a spectrum can be produced at any desired step size and over any desired variable range for accurate determination of amplitudes, frequencies, and phases corresponding to isolated peaks. Unlike limitations in DFT and FFT methods, explicit numerical integration can have any desired step size and compute the Fourier transform over any desired range of the conjugate Fourier transform variable (for example, frequency).


Discrete Fourier transforms and fast Fourier transforms

If the ordered pairs representing the original input function are equally spaced in their input variable (for example, equal time steps), then the Fourier transform is known as a
discrete Fourier transform In mathematics, the discrete Fourier transform (DFT) converts a finite sequence of equally-spaced samples of a function into a same-length sequence of equally-spaced samples of the discrete-time Fourier transform (DTFT), which is a complex- ...
(DFT), which can be computed either by explicit numerical integration, by explicit evaluation of the DFT definition, or by
fast Fourier transform A fast Fourier transform (FFT) is an algorithm that computes the discrete Fourier transform (DFT) of a sequence, or its inverse (IDFT). Fourier analysis converts a signal from its original domain (often time or space) to a representation in th ...
(FFT) methods. In contrast to explicit integration of input data, use of the DFT and FFT methods produces Fourier transforms described by ordered pairs of step size equal to the reciprocal of the original sampling interval. For example, if the input data is sampled every 10 seconds, the output of DFT and FFT methods will have a 0.1 Hz frequency spacing.


Tables of important Fourier transforms

The following tables record some closed-form Fourier transforms. For functions and denote their Fourier transforms by and . Only the three most common conventions are included. It may be useful to notice that entry 105 gives a relationship between the Fourier transform of a function and the original function, which can be seen as relating the Fourier transform and its inverse.


Functional relationships, one-dimensional

The Fourier transforms in this table may be found in or .


Square-integrable functions, one-dimensional

The Fourier transforms in this table may be found in , , or .


Distributions, one-dimensional

The Fourier transforms in this table may be found in or . {, class="wikitable" ! !! Function !! Fourier transform
unitary, ordinary frequency !! Fourier transform
unitary, angular frequency !! Fourier transform
non-unitary, angular frequency !! Remarks , - , , f(x)\, , \begin{align} &\hat{f}(\xi) \triangleq \hat f_1(\xi) \\&= \int_{-\infty}^\infty f(x) e^{-2\pi i x\xi}\, dx \end{align} , \begin{align} &\hat{f}(\omega) \triangleq \hat f_2(\omega) \\&= \frac{1}{\sqrt{2 \pi \int_{-\infty}^\infty f(x) e^{-i \omega x}\, dx \end{align} , \begin{align} &\hat{f}(\omega) \triangleq \hat f_3(\omega) \\&= \int_{-\infty}^\infty f(x) e^{-i \omega x}\, dx \end{align} , Definitions , - , 301 , 1 , \delta(\xi) , \sqrt{2\pi}\, \delta(\omega) , 2\pi\delta(\omega) , The distribution denotes the
Dirac delta function In mathematics, the Dirac delta distribution ( distribution), also known as the unit impulse, is a generalized function or distribution over the real numbers, whose value is zero everywhere except at zero, and whose integral over the entire ...
. , - , 302 , \delta(x)\, , 1 , \frac{1}{\sqrt{2\pi\, , 1 , Dual of rule 301. , - , 303 , e^{i a x} , \delta\left(\xi - \frac{a}{2\pi}\right) , \sqrt{2 \pi}\, \delta(\omega - a) , 2 \pi\delta(\omega - a) , This follows from 103 and 301. , - , 304 , \cos (a x) , \frac{ \delta\left(\xi - \frac{a}{2\pi}\right)+\delta\left(\xi+\frac{a}{2\pi}\right)}{2} , \sqrt{2 \pi}\,\frac{\delta(\omega-a)+\delta(\omega+a)}{2} , \pi\left(\delta(\omega-a)+\delta(\omega+a)\right) , This follows from rules 101 and 303 using
Euler's formula Euler's formula, named after Leonhard Euler, is a mathematical formula in complex analysis that establishes the fundamental relationship between the trigonometric functions and the complex exponential function. Euler's formula states that for an ...
:
\cos(a x) = \frac{e^{i a x} + e^{-i a x{2}. , - , 305 , \sin( ax) , \frac{\delta\left(\xi-\frac{a}{2\pi}\right)-\delta\left(\xi+\frac{a}{2\pi}\right)}{2i} , \sqrt{2 \pi}\,\frac{\delta(\omega-a)-\delta(\omega+a)}{2i} , -i\pi\bigl(\delta(\omega-a)-\delta(\omega+a)\bigr) , This follows from 101 and 303 using
\sin(a x) = \frac{e^{i a x} - e^{-i a x{2i}. , - , 306 , \cos \left( a x^2 \right) , \sqrt{\frac{\pi}{a \cos \left( \frac{\pi^2 \xi^2}{a} - \frac{\pi}{4} \right) , \frac{1}{\sqrt{2 a \cos \left( \frac{\omega^2}{4 a} - \frac{\pi}{4} \right) , \sqrt{\frac{\pi}{a \cos \left( \frac{\omega^2}{4a} - \frac{\pi}{4} \right) , This follows from 101 and 207 using
\cos(a x^2) = \frac{e^{i a x^2} + e^{-i a x^2{2}. , - , 307 , \sin \left( a x^2 \right) , - \sqrt{\frac{\pi}{a \sin \left( \frac{\pi^2 \xi^2}{a} - \frac{\pi}{4} \right) , \frac{-1}{\sqrt{2 a \sin \left( \frac{\omega^2}{4 a} - \frac{\pi}{4} \right) , -\sqrt{\frac{\pi}{a\sin \left( \frac{\omega^2}{4a} - \frac{\pi}{4} \right) , This follows from 101 and 207 using
\sin(a x^2) = \frac{e^{i a x^2} - e^{-i a x^2{2i}. , - , 308 , x^n\, , \left(\frac{i}{2\pi}\right)^n \delta^{(n)} (\xi) , i^n \sqrt{2\pi} \delta^{(n)} (\omega) , 2\pi i^n\delta^{(n)} (\omega) , Here, is a
natural number In mathematics, the natural numbers are those numbers used for counting (as in "there are ''six'' coins on the table") and ordering (as in "this is the ''third'' largest city in the country"). Numbers used for counting are called ''Cardinal n ...
and is the th distribution derivative of the Dirac delta function. This rule follows from rules 107 and 301. Combining this rule with 101, we can transform all
polynomial In mathematics, a polynomial is an expression consisting of indeterminates (also called variables) and coefficients, that involves only the operations of addition, subtraction, multiplication, and positive-integer powers of variables. An exa ...
s. , - , , \delta^{(n)}(x) , (2\pi i\xi)^n , \frac{(i\omega)^n}{\sqrt{2\pi , (i\omega)^n , Dual of rule 308. is the th distribution derivative of the Dirac delta function. This rule follows from 106 and 302. , - , 309 , \frac{1}{x} , -i\pi\sgn(\xi) , -i\sqrt{\frac{\pi}{2\sgn(\omega) , -i\pi\sgn(\omega) , Here is the
sign function In mathematics, the sign function or signum function (from '' signum'', Latin for "sign") is an odd mathematical function that extracts the sign of a real number. In mathematical expressions the sign function is often represented as . To avoi ...
. Note that is not a distribution. It is necessary to use the
Cauchy principal value In mathematics, the Cauchy principal value, named after Augustin Louis Cauchy, is a method for assigning values to certain improper integrals which would otherwise be undefined. Formulation Depending on the type of singularity in the integrand , ...
when testing against
Schwartz functions In mathematics, Schwartz space \mathcal is the function space of all functions whose derivatives are rapidly decreasing. This space has the important property that the Fourier transform is an automorphism on this space. This property enables on ...
. This rule is useful in studying the
Hilbert transform In mathematics and in signal processing, the Hilbert transform is a specific linear operator that takes a function, of a real variable and produces another function of a real variable . This linear operator is given by convolution with the functi ...
. , - , 310 , \begin{align} &\frac{1}{x^n} \\ &:= \frac{(-1)^{n-1{(n-1)!}\frac{d^n}{dx^n}\log , x, \end{align} , -i\pi \frac{(-2\pi i\xi)^{n-1{(n-1)!} \sgn(\xi) , -i\sqrt{\frac{\pi}{2\, \frac{(-i\omega)^{n-1{(n-1)!}\sgn(\omega) , -i\pi \frac{(-i\omega)^{n-1{(n-1)!}\sgn(\omega) , is the homogeneous distribution defined by the distributional derivative
\frac{(-1)^{n-1{(n-1)!}\frac{d^n}{dx^n}\log, x, , - , 311 , , x, ^\alpha , -\frac{2\sin\left(\frac{\pi\alpha}{2}\right)\Gamma(\alpha+1)}{, 2\pi\xi, ^{\alpha+1 , \frac{-2}{\sqrt{2\pi\, \frac{\sin\left(\frac{\pi\alpha}{2}\right)\Gamma(\alpha+1)}{, \omega, ^{\alpha+1 , -\frac{2\sin\left(\frac{\pi\alpha}{2}\right)\Gamma(\alpha+1)}{, \omega, ^{\alpha+1 , This formula is valid for . For some singular terms arise at the origin that can be found by differentiating 318. If , then is a locally integrable function, and so a tempered distribution. The function is a holomorphic function from the right half-plane to the space of tempered distributions. It admits a unique meromorphic extension to a tempered distribution, also denoted for (See homogeneous distribution.) , - , , \frac{1}{\sqrt{, x} , \frac{1}{\sqrt{, \xi} , \frac{1}{\sqrt{, \omega} , \frac{\sqrt{2\pi{\sqrt{, \omega} , Special case of 311. , - , 312 , \sgn(x) , \frac{1}{i\pi \xi} , \sqrt{\frac{2}{\pi \frac{1}{i\omega } , \frac{2}{i\omega } , The dual of rule 309. This time the Fourier transforms need to be considered as a
Cauchy principal value In mathematics, the Cauchy principal value, named after Augustin Louis Cauchy, is a method for assigning values to certain improper integrals which would otherwise be undefined. Formulation Depending on the type of singularity in the integrand , ...
. , - , 313 , u(x) , \frac{1}{2}\left(\frac{1}{i \pi \xi} + \delta(\xi)\right) , \sqrt{\frac{\pi}{2 \left( \frac{1}{i \pi \omega} + \delta(\omega)\right) , \pi\left( \frac{1}{i \pi \omega} + \delta(\omega)\right) , The function is the Heaviside
unit step function The Heaviside step function, or the unit step function, usually denoted by or (but sometimes , or ), is a step function, named after Oliver Heaviside (1850–1925), the value of which is zero for negative arguments and one for positive argume ...
; this follows from rules 101, 301, and 312. , - , 314 , \sum_{n=-\infty}^{\infty} \delta (x - n T) , \frac{1}{T} \sum_{k=-\infty}^{\infty} \delta \left( \xi -\frac{k }{T}\right) , \frac{\sqrt{2\pi {T}\sum_{k=-\infty}^{\infty} \delta \left( \omega -\frac{2\pi k}{T}\right) , \frac{2\pi}{T}\sum_{k=-\infty}^{\infty} \delta \left( \omega -\frac{2\pi k}{T}\right) , This function is known as the
Dirac comb In mathematics, a Dirac comb (also known as shah function, impulse train or sampling function) is a periodic function with the formula \operatorname_(t) \ := \sum_^ \delta(t - k T) for some given period T. Here ''t'' is a real variable and the ...
function. This result can be derived from 302 and 102, together with the fact that
\begin{align} & \sum_{n=-\infty}^{\infty} e^{inx} \\ = {}& 2\pi\sum_{k=-\infty}^{\infty} \delta(x+2\pi k) \end{align}
as distributions. , - , 315 , J_0 (x) , \frac{2\, \operatorname{rect}(\pi\xi)}{\sqrt{1 - 4 \pi^2 \xi^2 , \sqrt{\frac{2}{\pi \, \frac{\operatorname{rect}\left( \frac{\omega}{2} \right)}{\sqrt{1 - \omega^2 , \frac{2\,\operatorname{rect}\left(\frac{\omega}{2} \right)}{\sqrt{1 - \omega^2 , The function is the zeroth order
Bessel function Bessel functions, first defined by the mathematician Daniel Bernoulli and then generalized by Friedrich Bessel, are canonical solutions of Bessel's differential equation x^2 \frac + x \frac + \left(x^2 - \alpha^2 \right)y = 0 for an arbitrary ...
of first kind. , - , 316 , J_n (x) , \frac{2 (-i)^n T_n (2 \pi \xi) \operatorname{rect}(\pi \xi)}{\sqrt{1 - 4 \pi^2 \xi^2 , \sqrt{\frac{2}{\pi \frac{ (-i)^n T_n (\omega) \operatorname{rect} \left( \frac{\omega}{2} \right)}{\sqrt{1 - \omega^2 , \frac{2(-i)^n T_n (\omega) \operatorname{rect} \left( \frac{\omega}{2} \right)}{\sqrt{1 - \omega^2 , This is a generalization of 315. The function is the th order
Bessel function Bessel functions, first defined by the mathematician Daniel Bernoulli and then generalized by Friedrich Bessel, are canonical solutions of Bessel's differential equation x^2 \frac + x \frac + \left(x^2 - \alpha^2 \right)y = 0 for an arbitrary ...
of first kind. The function is the
Chebyshev polynomial of the first kind The Chebyshev polynomials are two sequences of polynomials related to the cosine and sine functions, notated as T_n(x) and U_n(x). They can be defined in several equivalent ways, one of which starts with trigonometric functions: The Chebyshe ...
. , - , 317 , \log \left, x \ , -\frac{1}{2} \frac{1}{\left, \xi \right - \gamma \delta \left( \xi \right) , -\frac{\sqrt\frac{\pi}{2{\left, \omega \right - \sqrt{2 \pi} \gamma \delta \left( \omega \right) , -\frac{\pi}{\left, \omega \right - 2 \pi \gamma \delta \left( \omega \right) , is the
Euler–Mascheroni constant Euler's constant (sometimes also called the Euler–Mascheroni constant) is a mathematical constant usually denoted by the lowercase Greek letter gamma (). It is defined as the limiting difference between the harmonic series and the natural l ...
. It is necessary to use a finite part integral when testing } or }against
Schwartz functions In mathematics, Schwartz space \mathcal is the function space of all functions whose derivatives are rapidly decreasing. This space has the important property that the Fourier transform is an automorphism on this space. This property enables on ...
. The details of this might change the coefficient of the delta function. , - , 318 , \left( \mp ix \right)^{-\alpha} , \frac{\left(2\pi\right)^\alpha}{\Gamma\left(\alpha\right)}u\left(\pm \xi \right)\left(\pm \xi \right)^{\alpha-1} , \frac{\sqrt{2\pi{\Gamma\left(\alpha\right)}u\left(\pm\omega\right)\left(\pm\omega\right)^{\alpha-1} , \frac{2\pi}{\Gamma\left(\alpha\right)}u\left(\pm\omega\right)\left(\pm\omega\right)^{\alpha-1} , This formula is valid for . Use differentiation to derive formula for higher exponents. is the Heaviside function.


Two-dimensional functions

{, class="wikitable" ! !! Function !! Fourier transform
unitary, ordinary frequency !! Fourier transform
unitary, angular frequency !! Fourier transform
non-unitary, angular frequency !! Remarks , - , 400 , f(x,y) , \begin{align}& \hat{f}(\xi_x, \xi_y)\triangleq \\ & \iint f(x,y) e^{-2\pi i(\xi_x x+\xi_y y)}\,dx\,dy \end{align} , \begin{align}& \hat{f}(\omega_x,\omega_y)\triangleq \\ & \frac{1}{2 \pi} \iint f(x,y) e^{-i (\omega_x x +\omega_y y)}\, dx\,dy \end{align} , \begin{align}& \hat{f}(\omega_x,\omega_y)\triangleq \\ & \iint f(x,y) e^{-i(\omega_x x+\omega_y y)}\, dx\,dy \end{align} , The variables , , , are real numbers. The integrals are taken over the entire plane. , - , 401 , e^{-\pi\left(a^2x^2+b^2y^2\right)} , \frac{1}{, ab e^{-\pi\left(\frac{\xi_x^2}{a^2} + \frac{\xi_y^2}{b^2}\right)} , \frac{1}{2\pi\,, ab e^{-\frac{1}{4\pi}\left(\frac{\omega_x^2}{a^2} + \frac{\omega_y^2}{b^2}\right)} , \frac{1}{, ab e^{-\frac{1}{4\pi}\left(\frac{\omega_x^2}{a^2} + \frac{\omega_y^2}{b^2}\right)} , Both functions are Gaussians, which may not have unit volume. , - , 402 , \operatorname{circ}\left(\sqrt{x^2+y^2}\right) , \frac{J_1\left(2 \pi \sqrt{\xi_x^2+\xi_y^2}\right)}{\sqrt{\xi_x^2+\xi_y^2 , \frac{J_1\left(\sqrt{\omega_x^2+\omega_y^2}\right)}{\sqrt{\omega_x^2+\omega_y^2 , \frac{2\pi J_1\left(\sqrt{\omega_x^2+\omega_y^2}\right)}{\sqrt{\omega_x^2+\omega_y^2 , The function is defined by for , and is 0 otherwise. The result is the amplitude distribution of the
Airy disk In optics, the Airy disk (or Airy disc) and Airy pattern are descriptions of the best- focused spot of light that a perfect lens with a circular aperture can make, limited by the diffraction of light. The Airy disk is of importance in physics, ...
, and is expressed using (the order-1
Bessel function Bessel functions, first defined by the mathematician Daniel Bernoulli and then generalized by Friedrich Bessel, are canonical solutions of Bessel's differential equation x^2 \frac + x \frac + \left(x^2 - \alpha^2 \right)y = 0 for an arbitrary ...
of the first kind). , - , 403 , \frac{1}{\sqrt{x^2+y^2 , \frac{1}{\sqrt{\xi_x^2+\xi_y^2 , \frac{1}{\sqrt{\omega_x^2+\omega_y^2 , \frac{2\pi}{\sqrt{\omega_x^2+\omega_y^2 , This is the
Hankel transform In mathematics, the Hankel transform expresses any given function ''f''(''r'') as the weighted sum of an infinite number of Bessel functions of the first kind . The Bessel functions in the sum are all of the same order ν, but differ in a scaling ...
of , a 2-D Fourier "self-transform". , - , 404 , \frac{i}{x+i y} , \frac{1}{\xi_x+i\xi_y} , \frac{1}{\omega_x+i\omega_y} , \frac{2\pi}{\omega_x+i\omega_y} ,


Formulas for general -dimensional functions

{, class="wikitable" ! !! Function !! Fourier transform
unitary, ordinary frequency !! Fourier transform
unitary, angular frequency !! Fourier transform
non-unitary, angular frequency !! Remarks , - , 500 , f(\mathbf x)\, , \begin{align} &\hat{f}(\boldsymbol \xi) \triangleq \\ &\int_{\mathbb{R}^n}f(\mathbf x) e^{-2\pi i \mathbf x \cdot \boldsymbol \xi }\, d \mathbf x \end{align} , \begin{align} &\hat{f}(\boldsymbol \omega) \triangleq \\ &\frac{1} \int_{\mathbb{R}^n} f(\mathbf x) e^{-i \boldsymbol \omega \cdot \mathbf x}\, d \mathbf x \end{align} , \begin{align} &\hat{f}(\boldsymbol \omega) \triangleq \\ &\int_{\mathbb{R}^n}f(\mathbf x) e^{-i \mathbf x \cdot \boldsymbol \omega }\, d \mathbf x \end{align} , , - , 501 , \chi_{ ,1(, \mathbf x, )\left(1-, \mathbf x, ^2\right)^\delta , \frac{\Gamma(\delta+1)}{\pi^\delta\,, \boldsymbol \xi, ^{\frac{n}{2} + \delta J_{\frac{n}{2}+\delta}(2\pi, \boldsymbol \xi, ) , 2^\delta \, \frac{\Gamma(\delta+1)}{\left, \boldsymbol \omega\^{\frac{n}{2}+\delta J_{\frac{n}{2}+\delta}(, \boldsymbol \omega, ) , \frac{\Gamma(\delta+1)}{\pi^\delta} \left, \frac{\boldsymbol \omega}{2\pi}\^{-\frac{n}{2}-\delta} J_{\frac{n}{2}+\delta}(\!, \boldsymbol \omega, \!) , The function is the
indicator function In mathematics, an indicator function or a characteristic function of a subset of a set is a function that maps elements of the subset to one, and all other elements to zero. That is, if is a subset of some set , one has \mathbf_(x)=1 if x\i ...
of the interval . The function is the gamma function. The function is a Bessel function of the first kind, with order . Taking and produces 402. , - , 502 , , \mathbf x, ^{-\alpha}, \quad 0 < \operatorname{Re} \alpha < n. , \frac{(2\pi)^{\alpha{c_{n, \alpha , \boldsymbol \xi, ^{-(n - \alpha)} , \frac{(2\pi)^{\frac{n}{2}{c_{n, \alpha , \boldsymbol \omega, ^{-(n - \alpha)} , \frac{(2\pi)^{n{c_{n, \alpha , \boldsymbol \omega, ^{-(n - \alpha)} , See
Riesz potential In mathematics, the Riesz potential is a potential named after its discoverer, the Hungarian mathematician Marcel Riesz. In a sense, the Riesz potential defines an inverse for a power of the Laplace operator on Euclidean space. They generalize to ...
where the constant is given by
c_{n, \alpha} = \pi^\frac{n}{2} 2^\alpha \frac{\Gamma\left(\frac{\alpha}{2}\right)}{\Gamma\left(\frac{n - \alpha}{2}\right)}.
The formula also holds for all by analytic continuation, but then the function and its Fourier transforms need to be understood as suitably regularized tempered distributions. See homogeneous distribution.In , with the non-unitary conventions of this table, the transform of , \mathbf x, ^\lambda is given to be
2^{\lambda+n}\pi^{\tfrac12 n}\frac{\Gamma\left(\frac{\lambda+n}{2}\right)}{\Gamma\left(-\frac{\lambda}{2}\right)}, \boldsymbol\omega, ^{-\lambda-n}
from which this follows, with \lambda=-\alpha.
, - , 503 , \frac{1}{\left, \boldsymbol \sigma\\left(2\pi\right)^\frac{n}{2 e^{-\frac{1}{2} \mathbf x^{\mathrm T} \boldsymbol \sigma^{-\mathrm T} \boldsymbol \sigma^{-1} \mathbf x} , e^{-2\pi^2 \boldsymbol \xi^{\mathrm T} \boldsymbol \sigma \boldsymbol \sigma^{\mathrm T} \boldsymbol \xi} , (2\pi)^{-\frac{n}{2 e^{-\frac{1}{2} \boldsymbol \omega^{\mathrm T} \boldsymbol \sigma \boldsymbol \sigma^{\mathrm T} \boldsymbol \omega} , e^{-\frac{1}{2} \boldsymbol \omega^{\mathrm T} \boldsymbol \sigma \boldsymbol \sigma^{\mathrm T} \boldsymbol \omega} , This is the formula for a
multivariate normal distribution In probability theory and statistics, the multivariate normal distribution, multivariate Gaussian distribution, or joint normal distribution is a generalization of the one-dimensional (univariate) normal distribution to higher dimensions. One d ...
normalized to 1 with a mean of 0. Bold variables are vectors or matrices. Following the notation of the aforementioned page, and , - , 504 , e^{-2\pi\alpha, \mathbf x , \frac{c_n\alpha}{\left(\alpha^2+, \boldsymbol{\xi}, ^2\right)^\frac{n+1}{2 , \frac{c_n (2\pi)^{\frac{n+2}{2 \alpha}{\left(4\pi^2\alpha^2+, \boldsymbol{\omega}, ^2\right)^\frac{n+1}{2 , \frac{c_n (2\pi)^{n+1} \alpha}{\left(4\pi^2\alpha^2+, \boldsymbol{\omega}, ^2\right)^\frac{n+1}{2 , Here.
c_n=\frac{\Gamma\left(\frac{n+1}{2}\right)}{\pi^\frac{n+1}{2,


See also

*
Analog signal processing Analog signal processing is a type of signal processing conducted on continuous analog signals by some analog means (as opposed to the discrete digital signal processing where the signal processing is carried out by a digital process). "Analog" indi ...
*
Beevers–Lipson strip Beevers–Lipson strips were a computational aid for early crystallographers in calculating Fourier transforms to determine the structure of crystals from crystallographic data, enabling the creation of models for complex molecules. They were u ...
*
Constant-Q transform In mathematics and signal processing, the constant-Q transform and variable-Q transform, simply known as CQT and VQT, transforms a data series to the frequency domain. It is related to the Fourier transform Judith C. BrownCalculation of a constant ...
*
Discrete Fourier transform In mathematics, the discrete Fourier transform (DFT) converts a finite sequence of equally-spaced samples of a function into a same-length sequence of equally-spaced samples of the discrete-time Fourier transform (DTFT), which is a complex- ...
**
DFT matrix In applied mathematics, a DFT matrix is an expression of a discrete Fourier transform (DFT) as a transformation matrix, which can be applied to a signal through matrix multiplication. Definition An ''N''-point DFT is expressed as the multiplicati ...
*
Fast Fourier transform A fast Fourier transform (FFT) is an algorithm that computes the discrete Fourier transform (DFT) of a sequence, or its inverse (IDFT). Fourier analysis converts a signal from its original domain (often time or space) to a representation in th ...
*
Fourier integral operator In mathematical analysis, Fourier integral operators have become an important tool in the theory of partial differential equations. The class of Fourier integral operators contains differential operators as well as classical integral operators as ...
* Fourier inversion theorem * Fourier multiplier *
Fourier series A Fourier series () is a summation of harmonically related sinusoidal functions, also known as components or harmonics. The result of the summation is a periodic function whose functional form is determined by the choices of cycle length (or ''p ...
*
Fourier sine transform In mathematics, the Fourier sine and cosine transforms are forms of the Fourier transform that do not use complex numbers or require negative frequency. They are the forms originally used by Joseph Fourier and are still preferred in some application ...
*
Fourier–Deligne transform In algebraic geometry, the Fourier–Deligne transform, or ℓ-adic Fourier transform, or geometric Fourier transform, is an operation on objects of the derived category of ''ℓ''-adic sheaves over the affine line. It was introduced by Pierre Deli ...
*
Fourier–Mukai transform In algebraic geometry, a Fourier–Mukai transform ''Φ'K'' is a functor between derived categories of coherent sheaves D(''X'') → D(''Y'') for schemes ''X'' and ''Y'', which is, in a sense, an integral transform along a kernel object ''K'' ...
*
Fractional Fourier transform In mathematics, in the area of harmonic analysis, the fractional Fourier transform (FRFT) is a family of linear transformations generalizing the Fourier transform. It can be thought of as the Fourier transform to the ''n''-th power, where ''n'' n ...
*Indirect Fourier transform *Integral transform **
Hankel transform In mathematics, the Hankel transform expresses any given function ''f''(''r'') as the weighted sum of an infinite number of Bessel functions of the first kind . The Bessel functions in the sum are all of the same order ν, but differ in a scaling ...
**Hartley transform *
Laplace transform In mathematics, the Laplace transform, named after its discoverer Pierre-Simon Laplace (), is an integral transform In mathematics, an integral transform maps a function from its original function space into another function space via integra ...
*Least-squares spectral analysis *Linear canonical transform *Mellin transform *Multidimensional transform *NGC 4622, especially the image NGC 4622 Fourier transform . *Nonlocal operator *Quantum Fourier transform *Short-time Fourier transform *Spectral density **Spectral density estimation *Symbolic integration *Time stretch dispersive Fourier transform *Transform (mathematics)


Notes


Citations


References

*. *. *. *. *. *. *. *. *. *. *. *. *. *. *. *. * (translated from French). *. *. *. *. * (translated from Russian). * (translated from Russian). *. *. *. *. *. *. *. *. * (translated from Russian). *. * (translated from Russian). *. *; also available a
Fundamentals of Music Processing
Section 2.1, pages 40-56. *  Also available at https://d1.amobbs.com/bbs_upload782111/files_24/ourdev_523225.pdf. *. *. *. *. *. *. *. *. *. *. *. *. *. *. *. *. *. *. *. *.


External links

*
Encyclopedia of Mathematics
* {{DEFAULTSORT:Fourier Transform Fourier analysis Integral transforms Unitary operators Joseph Fourier Mathematical physics