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In mathematics, a Green's function is 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 impulse (). More generally, an impulse response is the reac ...
of an
inhomogeneous 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, si ...
linear differential operator defined on a domain with specified initial conditions or boundary conditions. This means that if \operatorname is the linear differential operator, then * the Green's function G is the solution of the equation \operatorname G = \delta, where \delta is Dirac's delta function; * the solution of the initial-value problem \operatorname y = f is the
convolution In mathematics (in particular, functional analysis), convolution is a mathematical operation on two functions ( and ) that produces a third function (f*g) that expresses how the shape of one is modified by the other. The term ''convolution' ...
(G \ast f). Through the
superposition principle The superposition principle, also known as superposition property, states that, for all linear systems, the net response caused by two or more stimuli is the sum of the responses that would have been caused by each stimulus individually. So th ...
, given a
linear ordinary differential equation In mathematics, a linear differential equation is a differential equation that is defined by a linear polynomial in the unknown function and its derivatives, that is an equation of the form :a_0(x)y + a_1(x)y' + a_2(x)y'' \cdots + a_n(x)y^ = b( ...
(ODE), \operatorname y = f, one can first solve \operatorname G = \delta_s, for each , and realizing that, since the source is a sum of
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 ...
s, the solution is a sum of Green's functions as well, by linearity of . Green's functions are named after the British
mathematician A mathematician is someone who uses an extensive knowledge of mathematics in their work, typically to solve mathematical problems. Mathematicians are concerned with numbers, data, quantity, mathematical structure, structure, space, Mathematica ...
George Green, who first developed the concept in the 1820s. In the modern study of linear
partial differential equation In mathematics, a partial differential equation (PDE) is an equation which imposes relations between the various partial derivatives of a multivariable function. The function is often thought of as an "unknown" to be solved for, similarly to ...
s, Green's functions are studied largely from the point of view of
fundamental solution In mathematics, a fundamental solution for a linear partial differential operator is a formulation in the language of distribution theory of the older idea of a Green's function (although unlike Green's functions, fundamental solutions do not a ...
s instead. Under many-body theory, the term is also used 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 rel ...
, specifically 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 a ...
,
aerodynamics Aerodynamics, from grc, ἀήρ ''aero'' (air) + grc, δυναμική (dynamics), is the study of the motion of air, particularly when affected by a solid object, such as an airplane wing. It involves topics covered in the field of fluid dyn ...
,
aeroacoustics Aeroacoustics is a branch of acoustics that studies noise generation via either turbulent fluid motion or aerodynamic forces interacting with surfaces. Noise generation can also be associated with periodically varying flows. A notable example of ...
,
electrodynamics In physics, electromagnetism is an interaction that occurs between particles with electric charge. It is the second-strongest of the four fundamental interactions, after the strong force, and it is the dominant force in the interactions o ...
,
seismology Seismology (; from Ancient Greek σεισμός (''seismós'') meaning "earthquake" and -λογία (''-logía'') meaning "study of") is the scientific study of earthquakes and the propagation of elastic waves through the Earth or through other ...
and
statistical field theory Statistics (from German: ''Statistik'', "description of a state, a country") is the discipline that concerns the collection, organization, analysis, interpretation, and presentation of data. In applying statistics to a scientific, industria ...
, to refer to various types of
correlation functions The cross-correlation matrix of two random vectors is a matrix containing as elements the cross-correlations of all pairs of elements of the random vectors. The cross-correlation matrix is used in various digital signal processing algorithms. D ...
, even those that do not fit the mathematical definition. In quantum field theory, Green's functions take the roles of
propagator In quantum mechanics and quantum field theory, the propagator is a function that specifies the probability amplitude for a particle to travel from one place to another in a given period of time, or to travel with a certain energy and momentum. ...
s.


Definition and uses

A Green's function, , of a linear differential operator \operatorname = \operatorname(x) acting on distributions over a subset of the
Euclidean space Euclidean space is the fundamental space of geometry, intended to represent physical space. Originally, that is, in Euclid's ''Elements'', it was the three-dimensional space of Euclidean geometry, but in modern mathematics there are Euclidean sp ...
\R^n, at a point , is any solution of where is 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 ...
. This property of a Green's function can be exploited to solve differential equations of the form If the
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 lea ...
of is non-trivial, then the Green's function is not unique. However, in practice, some combination of symmetry,
boundary condition In mathematics, in the field of differential equations, a boundary value problem is a differential equation together with a set of additional constraints, called the boundary conditions. A solution to a boundary value problem is a solution to ...
s and/or other externally imposed criteria will give a unique Green's function. Green's functions may be categorized, by the type of boundary conditions satisfied, by a Green's function number. Also, Green's functions in general are distributions, not necessarily functions of a real variable. Green's functions are also useful tools in solving
wave equation The (two-way) wave equation is a second-order linear partial differential equation for the description of waves or standing wave fields — as they occur in classical physics — such as mechanical waves (e.g. water waves, sound waves and s ...
s and
diffusion equation The diffusion equation is a parabolic partial differential equation. In physics, it describes the macroscopic behavior of many micro-particles in Brownian motion, resulting from the random movements and collisions of the particles (see Fick's law ...
s. 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, q ...
, Green's function of the Hamiltonian is a key concept with important links to the concept of
density of states In solid state physics and condensed matter physics, the density of states (DOS) of a system describes the number of modes per unit frequency range. The density of states is defined as D(E) = N(E)/V , where N(E)\delta E is the number of states ...
. The Green's function as used in physics is usually defined with the opposite sign, instead. That is, \operatorname \, G(x,s) = \delta(x-s)~. This definition does not significantly change any of the properties of Green's function due to the evenness of the Dirac delta function. If the operator is translation invariant, that is, when \operatorname has constant coefficients with respect to , then the Green's function can be taken to be a
convolution kernel In mathematics (in particular, functional analysis), convolution is a mathematical operation on two functions ( and ) that produces a third function (f*g) that expresses how the shape of one is modified by the other. The term ''convolution'' ...
, that is, G(x,s) = G(x-s)~. In this case, Green's function is the same as the impulse response of linear time-invariant system theory.


Motivation

Loosely speaking, if such a function can be found for the operator \operatorname, then, if we multiply the equation () for the Green's function by , and then integrate with respect to , we obtain, \int \operatorname\,G(x,s)\,f(s) \, ds = \int \delta(x-s) \, f(s) \, ds = f(x)~. Because the operator \operatorname = \operatorname(x) is linear and acts only on the variable (and ''not'' on the variable of integration ), one may take the operator \operatorname outside of the integration, yielding \operatorname\,\left(\int G(x,s)\,f(s) \,ds \right) = f(x)~. This means that is a solution to the equation \operatorname u(x) = f(x)~. Thus, one may obtain the function through knowledge of the Green's function in equation () and the source term on the right-hand side in equation (). This process relies upon the linearity of the operator \operatorname. In other words, the solution of equation (), , can be determined by the integration given in equation (). Although is known, this integration cannot be performed unless is also known. The problem now lies in finding the Green's function that satisfies equation (). For this reason, the Green's function is also sometimes called the
fundamental solution In mathematics, a fundamental solution for a linear partial differential operator is a formulation in the language of distribution theory of the older idea of a Green's function (although unlike Green's functions, fundamental solutions do not a ...
associated to the operator \operatorname. Not every operator \operatorname admits a Green's function. A Green's function can also be thought of as a right inverse of \operatorname. Aside from the difficulties of finding a Green's function for a particular operator, the integral in equation () may be quite difficult to evaluate. However the method gives a theoretically exact result. This can be thought of as an expansion of according to a
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 ...
basis (projecting over \delta(x - s); and a superposition of the solution on each projection. Such an integral equation is known as a
Fredholm integral equation In mathematics, the Fredholm integral equation is an integral equation whose solution gives rise to Fredholm theory, the study of Fredholm kernels and Fredholm operators. The integral equation was studied by Ivar Fredholm. A useful method to ...
, the study of which constitutes
Fredholm theory In mathematics, Fredholm theory is a theory of integral equations. In the narrowest sense, Fredholm theory concerns itself with the solution of the Fredholm integral equation. In a broader sense, the abstract structure of Fredholm's theory is given ...
.


Green's functions for solving inhomogeneous boundary value problems

The primary use of Green's functions in mathematics is to solve non-homogeneous
boundary value problem In mathematics, in the field of differential equations, a boundary value problem is a differential equation together with a set of additional constraints, called the boundary conditions. A solution to a boundary value problem is a solution to ...
s. In modern
theoretical physics Theoretical physics is a branch of physics that employs mathematical models and abstractions of physical objects and systems to rationalize, explain and predict natural phenomena. This is in contrast to experimental physics, which uses experi ...
, Green's functions are also usually used as
propagator In quantum mechanics and quantum field theory, the propagator is a function that specifies the probability amplitude for a particle to travel from one place to another in a given period of time, or to travel with a certain energy and momentum. ...
s in
Feynman diagram In theoretical physics, a Feynman diagram is a pictorial representation of the mathematical expressions describing the behavior and interaction of subatomic particles. The scheme is named after American physicist Richard Feynman, who introdu ...
s; the term ''Green's function'' is often further used for any
correlation function A correlation function is a function that gives the statistical correlation between random variables, contingent on the spatial or temporal distance between those variables. If one considers the correlation function between random variables re ...
.


Framework

Let \operatorname be the Sturm–Liouville operator, a linear differential operator of the form \operatorname=\dfrac\left (x) \dfrac\rightq(x) and let \vec\operatorname be the vector-valued
boundary condition In mathematics, in the field of differential equations, a boundary value problem is a differential equation together with a set of additional constraints, called the boundary conditions. A solution to a boundary value problem is a solution to ...
s operator \vec\operatorname\,u= \begin \alpha_1 u'(0)+\beta_1 u(0) \\ \alpha_2 u'(\ell)+\beta_2 u(\ell) \end ~. Let f(x) be a continuous function in ,\ell,. Further suppose that the problem \begin \operatorname\,u &= f \\ \vec\operatorname\,u &= \vec \end is "regular", i.e., the only solution for f(x) = 0 for all is u(x) = 0.


Theorem

There is one and only one solution u(x) that satisfies \begin \operatorname\,u & = f\\ \vec\operatorname\,u & = \vec \end and it is given by u(x)=\int_0^\ell f(s) \, G(x,s) \, ds~, where G(x,s) is a Green's function satisfying the following conditions: # G(x,s) is continuous in x and s. # For x \ne s~, \quad \operatorname\,G(x,s) = 0~. # For s \ne 0~, \quad \vec\operatorname\,G(x,s) = \vec~. #
Derivative In mathematics, the derivative of a function of a real variable measures the sensitivity to change of the function value (output value) with respect to a change in its argument (input value). Derivatives are a fundamental tool of calculus. ...
"jump": \quad G'(s_,s) - G'(s_,s) = 1 / p(s)~. # Symmetry: \quad G(x,s) = G(s,x)~.


Advanced and retarded Green's functions

Green's function is not necessarily unique since the addition of any solution of the homogeneous equation to one Green's function results in another Green's function. Therefore if the homogeneous equation has nontrivial solutions, multiple Green's functions exist. In some cases, it is possible to find one Green's function that is nonvanishing only for s \leq x, which is called a retarded Green's function, and another Green's function that is nonvanishing only for s \geq x , which is called an advanced Green's function. In such cases, any linear combination of the two Green's functions is also a valid Green's function. The terminology advanced and retarded is especially useful when the variable x corresponds to time. In such cases, the solution provided by the use of the retarded Green's function depends only on the past sources and is
causal Causality (also referred to as causation, or cause and effect) is influence by which one event, process, state, or object (''a'' ''cause'') contributes to the production of another event, process, state, or object (an ''effect'') where the ca ...
whereas the solution provided by the use of the advanced Green's function depends only on the future sources and is acausal. In these problems, it is often the case that the causal solution is the physically important one. The use of advanced and retarded Green's function is especially common for the analysis of solutions of the inhomogeneous electromagnetic wave equation.


Finding Green's functions


Units

While it doesn't uniquely fix the form the Green's function will take, performing a
dimensional analysis In engineering and science, dimensional analysis is the analysis of the relationships between different physical quantities by identifying their base quantities (such as length, mass, time, and electric current) and units of measure (such as ...
to find the units a Green's function must have is an important sanity check on any Green's function found through other means. A quick examination of the defining equation, L G(x, s) = \delta(x - s), shows that the units of G depend not only on the units of L but also on the number and units of the space of which the position vectors x and s are elements. This leads to the relationship: G = L^ d x^, where G is defined as, "the physical units of G", and d x is the
volume element In mathematics, a volume element provides a means for integrating a function with respect to volume in various coordinate systems such as spherical coordinates and cylindrical coordinates. Thus a volume element is an expression of the form :dV = ...
of the space (or
spacetime In physics, spacetime is a mathematical model that combines the three dimensions of space and one dimension of time into a single four-dimensional manifold. Spacetime diagrams can be used to visualize relativistic effects, such as why diffe ...
). For example, if L = \partial_t^2 and time is the only variable then: L = \text^, d x = \text,\ \text G = \text. If L = \square = \frac\partial_t^2-\nabla^2, the
d'Alembert operator In special relativity, electromagnetism and wave theory, the d'Alembert operator (denoted by a box: \Box), also called the d'Alembertian, wave operator, box operator or sometimes quabla operator (''cf''. nabla symbol) is the Laplace operator of M ...
, and space has 3 dimensions then: L = \text^, dx = \text \text^3,\ \text G = \text^ \text^.


Eigenvalue expansions

If a differential operator admits a set of
eigenvectors 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 ...
(i.e., a set of functions and scalars such that ) that is complete, then it is possible to construct a Green's function from these eigenvectors and
eigenvalues 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 ...
. "Complete" means that the set of functions satisfies the following
completeness relation In functional analysis, a branch of mathematics, the Borel functional calculus is a ''functional calculus'' (that is, an assignment of operator (mathematics), operators from commutative algebras to functions defined on their Spectrum of a ring, spe ...
, \delta(x-x') = \sum_^\infty \Psi_n^\dagger(x) \Psi_n(x'). Then the following holds, where \dagger represents complex conjugation. Applying the operator to each side of this equation results in the completeness relation, which was assumed. The general study of Green's function written in the above form, and its relationship to the
function space In mathematics, a function space is a set of functions between two fixed sets. Often, the domain and/or codomain will have additional structure which is inherited by the function space. For example, the set of functions from any set into a ve ...
s formed by the eigenvectors, is known as
Fredholm theory In mathematics, Fredholm theory is a theory of integral equations. In the narrowest sense, Fredholm theory concerns itself with the solution of the Fredholm integral equation. In a broader sense, the abstract structure of Fredholm's theory is given ...
. There are several other methods for finding Green's functions, including the
method of images The method of images (or method of mirror images) is a mathematical tool for solving differential equations, in which the domain of the sought function is extended by the addition of its mirror image with respect to a symmetry hyperplane. As a resu ...
,
separation of variables In mathematics, separation of variables (also known as the Fourier method) is any of several methods for solving ordinary and partial differential equations, in which algebra allows one to rewrite an equation so that each of two variables occurs ...
, and
Laplace transform In mathematics, the Laplace transform, named after its discoverer Pierre-Simon Laplace (), is an integral transform that converts a function of a real variable (usually t, in the ''time domain'') to a function of a complex variable s (in the ...
s.


Combining Green's functions

If the differential operator L can be factored as L = L_1 L_2 then the Green's function of L can be constructed from the Green's functions for L_1 and L_2: G(x, s) = \int G_2(x, s_1)\, G_1(s_1, s) \, d s_1. The above identity follows immediately from taking G(x, s) to be the representation of the right operator inverse of L, analogous to how for the invertible linear operator C, defined by C = (AB)^ = B^ A^, is represented by its matrix elements C_. A further identity follows for differential operators that are scalar polynomials of the derivative, L = P_N(\partial_x). The
fundamental theorem of algebra The fundamental theorem of algebra, also known as d'Alembert's theorem, or the d'Alembert–Gauss theorem, states that every non- constant single-variable polynomial with complex coefficients has at least one complex root. This includes polynomia ...
, combined with the fact that \partial_x commutes with itself, guarantees that the polynomial can be factored, putting L in the form: L = \prod_^N (\partial_x - z_i), where z_i are the zeros of P_N(z). Taking 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, ...
of L G(x, s) = \delta(x - s) with respect to both x and s gives: \widehat(k_x, k_s) = \frac. The fraction can then be split into a sum using a
partial fraction decomposition In algebra, the partial fraction decomposition or partial fraction expansion of a rational fraction (that is, a fraction such that the numerator and the denominator are both polynomials) is an operation that consists of expressing the fraction as ...
before Fourier transforming back to x and s space. This process yields identities that relate integrals of Green's functions and sums of the same. For example, if L = (\partial_x + \gamma) (\partial_x + \alpha)^2 then one form for its Green's function is: \begin G(x, s) & = \frac\Theta(x-s) e^ - \frac\Theta(x-s) e^ + \frac \Theta(x - s) \, (x - s) e^ \\ pt& = \int \Theta(x - s_1) (x - s_1) e^ \Theta(s_1 - s) e^ \, ds_1. \end While the example presented is tractable analytically, it illustrates a process that works when the integral is not trivial (for example, when \nabla^2 is the operator in the polynomial).


Table of Green's functions

The following table gives an overview of Green's functions of frequently appearing differential operators, where r = \sqrt, \rho = \sqrt, \Theta(t) is the
Heaviside 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 ...
, J_\nu(z) is a
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 ...
, I_\nu(z) is a modified Bessel function of the first kind, and K_\nu(z) is a modified Bessel function of the second kind. Where time () appears in the first column, the retarded (causal) Green's function is listed.


Green's functions for the Laplacian

Green's functions for linear differential operators involving the
Laplacian In mathematics, the Laplace operator or Laplacian is a differential operator given by the divergence of the gradient of a scalar function on Euclidean space. It is usually denoted by the symbols \nabla\cdot\nabla, \nabla^2 (where \nabla is ...
may be readily put to use using the second of
Green's identities In mathematics, Green's identities are a set of three identities in vector calculus relating the bulk with the boundary of a region on which differential operators act. They are named after the mathematician George Green, who discovered Green's ...
. To derive Green's theorem, begin with the divergence theorem (otherwise known as Gauss's theorem), \int_V \nabla \cdot \vec A\ dV=\int_S \vec A \cdot d\widehat\sigma ~. Let \vec A=\varphi\,\nabla\psi-\psi\,\nabla\varphi and substitute into Gauss' law. Compute \nabla\cdot\vec A and apply the product rule for the ∇ operator, \begin \nabla\cdot\vec A &=\nabla\cdot(\varphi\,\nabla\psi \;-\; \psi\,\nabla\varphi)\\ &=(\nabla\varphi)\cdot(\nabla\psi) \;+\; \varphi\,\nabla^2\psi \;-\; (\nabla\varphi)\cdot(\nabla\psi) \;-\; \psi\nabla^2\varphi\\ &=\varphi\,\nabla^2\psi \;-\; \psi\,\nabla^2\varphi. \end Plugging this into the divergence theorem produces
Green's theorem In vector calculus, Green's theorem relates a line integral around a simple closed curve to a double integral over the plane region bounded by . It is the two-dimensional special case of Stokes' theorem. Theorem Let be a positively ori ...
, \int_V (\varphi\,\nabla^2\psi-\psi\,\nabla^2\varphi) \, dV = \int_S (\varphi\,\nabla\psi-\psi\nabla\,\varphi)\cdot d\widehat\sigma. Suppose that the linear differential operator is the
Laplacian In mathematics, the Laplace operator or Laplacian is a differential operator given by the divergence of the gradient of a scalar function on Euclidean space. It is usually denoted by the symbols \nabla\cdot\nabla, \nabla^2 (where \nabla is ...
, ∇2, and that there is a Green's function for the Laplacian. The defining property of the Green's function still holds, L G(x,x')=\nabla^2 G(x,x')=\delta(x-x'). Let \psi=G in Green's second identity, see
Green's identities In mathematics, Green's identities are a set of three identities in vector calculus relating the bulk with the boundary of a region on which differential operators act. They are named after the mathematician George Green, who discovered Green's ...
. Then, \int_V \left \varphi(x') \delta(x-x')-G(x,x') \, ^2\,\varphi(x')\right d^3x' = \int_S \left varphi(x')\, G(x,x')-G(x,x')\,\varphi(x')\right\cdot d\widehat\sigma'. Using this expression, it is possible to solve
Laplace's equation In mathematics and physics, Laplace's equation is a second-order partial differential equation named after Pierre-Simon Laplace, who first studied its properties. This is often written as \nabla^2\! f = 0 or \Delta f = 0, where \Delta = \na ...
2''φ''(''x'') = 0 or
Poisson's equation Poisson's equation is an elliptic partial differential equation of broad utility in theoretical physics. For example, the solution to Poisson's equation is the potential field caused by a given electric charge or mass density distribution; with t ...
2''φ''(''x'') = −''ρ''(''x''), subject to either
Neumann Neumann is German language, German and Yiddish language, Yiddish for "new man", and one of the List of the most common surnames in Europe#Germany, 20 most common German surnames. People * Von Neumann family, a Jewish Hungarian noble family A ...
or
Dirichlet Johann Peter Gustav Lejeune Dirichlet (; 13 February 1805 – 5 May 1859) was a German mathematician who made deep contributions to number theory (including creating the field of analytic number theory), and to the theory of Fourier series and ...
boundary conditions. In other words, we can solve for ''φ''(''x'') everywhere inside a volume where either (1) the value of ''φ''(''x'') is specified on the bounding surface of the volume (Dirichlet boundary conditions), or (2) the normal derivative of ''φ''(''x'') is specified on the bounding surface (Neumann boundary conditions). Suppose the problem is to solve for ''φ''(''x'') inside the region. Then the integral \int_V \varphi(x')\delta(x-x')\, d^3x' reduces to simply ''φ''(''x'') due to the defining property of 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 ...
and we have \varphi(x) = -\int_V G(x,x') \rho(x')\ d^3x' + \int_S \left varphi(x') \, \nabla' G(x,x')-G(x,x') \,\nabla'\varphi(x')\right\cdot d\widehat\sigma'. This form expresses the well-known property of
harmonic function In mathematics, mathematical physics and the theory of stochastic processes, a harmonic function is a twice continuously differentiable function f: U \to \mathbb R, where is an open subset of that satisfies Laplace's equation, that is, ...
s, that ''if the value or normal derivative is known on a bounding surface, then the value of the function inside the volume is known everywhere''. In
electrostatics Electrostatics is a branch of physics that studies electric charges at rest (static electricity). Since classical times, it has been known that some materials, such as amber, attract lightweight particles after rubbing. The Greek word for am ...
, ''φ''(''x'') is interpreted as the
electric potential The electric potential (also called the ''electric field potential'', potential drop, the electrostatic potential) is defined as the amount of work energy needed to move a unit of electric charge from a reference point to the specific point in ...
, ''ρ''(''x'') as
electric charge Electric charge is the physical property of matter that causes charged matter to experience a force when placed in an electromagnetic field. Electric charge can be ''positive'' or ''negative'' (commonly carried by protons and electrons respecti ...
density Density (volumetric mass density or specific mass) is the substance's mass per unit of volume. The symbol most often used for density is ''ρ'' (the lower case Greek letter rho), although the Latin letter ''D'' can also be used. Mathematicall ...
, and the normal derivative \nabla\varphi(x')\cdot d\widehat\sigma' as the normal component of the electric field. If the problem is to solve a Dirichlet boundary value problem, the Green's function should be chosen such that ''G''(''x'',''x''′) vanishes when either ''x'' or ''x''′ is on the bounding surface. Thus only one of the two terms in the
surface integral In mathematics, particularly multivariable calculus, a surface integral is a generalization of multiple integrals to integration over surfaces. It can be thought of as the double integral analogue of the line integral. Given a surface, on ...
remains. If the problem is to solve a Neumann boundary value problem, it might seem logical to choose Green's function so that its normal derivative vanishes on the bounding surface. However, application of Gauss's theorem to the differential equation defining the Green's function yields \int_S \nabla' G(x,x') \cdot d\widehat\sigma' = \int_V \nabla'^2 G(x,x') d^3x' = \int_V \delta (x-x') d^3x' = 1 ~, meaning the normal derivative of ''G''(''x'',''x''′) cannot vanish on the surface, because it must integrate to 1 on the surface. The simplest form the normal derivative can take is that of a constant, namely 1/''S'', where ''S'' is the surface area of the surface. The surface term in the solution becomes \int_S \varphi(x') \, \nabla' G(x,x')\cdot d\widehat\sigma' = \langle\varphi\rangle_S where \langle\varphi\rangle_S is the average value of the potential on the surface. This number is not known in general, but is often unimportant, as the goal is often to obtain the electric field given by the gradient of the potential, rather than the potential itself. With no boundary conditions, the Green's function for the Laplacian (
Green's function for the three-variable Laplace equation In physics, the Green's function (or fundamental solution) for Laplace's equation in three variables is used to describe the response of a particular type of physical system to a point source. In particular, this Green's function arises in sy ...
) is G(x,x')=-\dfrac. Supposing that the bounding surface goes out to infinity and plugging in this expression for the Green's function finally yields the standard expression for electric potential in terms of electric charge density as


Example

Find the Green function for the following problem, whose Green's function number is X11: \begin Lu & = u'' + k^2 u = f(x)\\ u(0)& = 0, \quad u\left(\tfrac\right) = 0. \end First step: The Green's function for the linear operator at hand is defined as the solution to If x\ne s, then the delta function gives zero, and the general solution is G(x,s)=c_1 \cos kx+c_2 \sin kx. For x, the boundary condition at x=0 implies G(0,s)=c_1 \cdot 1+c_2 \cdot 0=0, \quad c_1 = 0 if x < s and s \ne \tfrac. For x>s, the boundary condition at x=\tfrac implies G\left(\tfrac,s\right) = c_3 \cdot 0+c_4 \cdot 1=0, \quad c_4 = 0 The equation of G(0,s)=0 is skipped for similar reasons. To summarize the results thus far: G(x,s)= \begin c_2 \sin kx, & \textx Second step: The next task is to determine c_2 and c_3. Ensuring continuity in the Green's function at x=s implies c_2 \sin ks=c_3 \cos ks One can ensure proper discontinuity in the first derivative by integrating the defining differential equation (i.e., ) from x=s-\varepsilon to x=s+\varepsilon and taking the limit as \varepsilon goes to zero. Note that we only integrate the second derivative as the remaining term will be continuous by construction. c_3 \cdot (-k \sin ks)-c_2 \cdot (k \cos ks)=1 The two (dis)continuity equations can be solved for c_2 and c_3 to obtain c_2 = -\frac \quad;\quad c_3 = -\frac So Green's function for this problem is: G(x,s)=\begin -\frac \sin kx, & x


Further examples

* Let and let the subset be all of R. Let be \frac. Then, the
Heaviside 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 ...
is a Green's function of at . * Let and let the subset be the quarter-plane and be the
Laplacian In mathematics, the Laplace operator or Laplacian is a differential operator given by the divergence of the gradient of a scalar function on Euclidean space. It is usually denoted by the symbols \nabla\cdot\nabla, \nabla^2 (where \nabla is ...
. Also, assume a
Dirichlet boundary condition In the mathematical study of differential equations, the Dirichlet (or first-type) boundary condition is a type of boundary condition, named after Peter Gustav Lejeune Dirichlet (1805–1859). When imposed on an ordinary or a partial differenti ...
is imposed at and a
Neumann boundary condition In mathematics, the Neumann (or second-type) boundary condition is a type of boundary condition, named after Carl Neumann. When imposed on an ordinary or a partial differential equation, the condition specifies the values of the derivative appli ...
is imposed at . Then the X10Y20 Green's function is \begin G(x, y, x_0, y_0) =\dfrac &\left pt&\left. + \ln\sqrt- \ln\sqrt \, \right">ln\sqrt-\ln\sqrt \right. \\ pt&\left. + \ln\sqrt- \ln\sqrt \, \right \end * Let a < x < b , and all three are elements of the real numbers. Then, for any function f:\mathbb\to\mathbb with an n-th derivative that is integrable over the interval
, b The comma is a punctuation mark that appears in several variants in different languages. It has the same shape as an apostrophe or single closing quotation mark () in many typefaces, but it differs from them in being placed on the baseline o ...
/math>: \begin f(x) & = \sum_^ \frac \left \frac \right + \int_a^b \left frac \Theta(x - s)\right\left \frac \right ds \end ~. The Green's function in the above equation, G(x,s) = \frac \Theta(x - s), is not unique. How is the equation modified if g(x-s) is added to G(x,s), where g(x) satisfies \frac = 0 for all x \in
, b The comma is a punctuation mark that appears in several variants in different languages. It has the same shape as an apostrophe or single closing quotation mark () in many typefaces, but it differs from them in being placed on the baseline o ...
/math> (for example, g(x) = -x/2 with Also, compare the above equation to the form of a
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 se ...
centered at x = a.


See also

* Bessel potential * Discrete Green's functions – defined on graphs and grids *
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 impulse (). More generally, an impulse response is the reac ...
– the analog of a Green's function in signal processing *
Transfer function In engineering, a transfer function (also known as system function or network function) of a system, sub-system, or component is a mathematical function that theoretically models the system's output for each possible input. They are widely used ...
*
Fundamental solution In mathematics, a fundamental solution for a linear partial differential operator is a formulation in the language of distribution theory of the older idea of a Green's function (although unlike Green's functions, fundamental solutions do not a ...
* Green's function in many-body theory *
Correlation function A correlation function is a function that gives the statistical correlation between random variables, contingent on the spatial or temporal distance between those variables. If one considers the correlation function between random variables re ...
*
Propagator In quantum mechanics and quantum field theory, the propagator is a function that specifies the probability amplitude for a particle to travel from one place to another in a given period of time, or to travel with a certain energy and momentum. ...
*
Green's identities In mathematics, Green's identities are a set of three identities in vector calculus relating the bulk with the boundary of a region on which differential operators act. They are named after the mathematician George Green, who discovered Green's ...
*
Parametrix In mathematics, and specifically the field of partial differential equations (PDEs), a parametrix is an approximation to a fundamental solution of a PDE, and is essentially an approximate inverse to a differential operator. A parametrix for a di ...
* Volterra integral equation *
Resolvent formalism In mathematics, the resolvent formalism is a technique for applying concepts from complex analysis to the study of the spectrum of operators on Banach spaces and more general spaces. Formal justification for the manipulations can be found in the fr ...
* Keldysh formalism *
Spectral theory In mathematics, spectral theory is an inclusive term for theories extending the eigenvector and eigenvalue theory of a single square matrix to a much broader theory of the structure of operators in a variety of mathematical spaces. It is a result ...
* Multiscale Green's function


Footnotes


References

* *
''Chapter 5 contains a very readable account of using Green's functions to solve boundary value problems in electrostatics.'' * * * * * * *


External links

* * * * *
Introduction to the Keldysh Nonequilibrium Green Function Technique
by A. P. Jauho





* ttp://en.citizendium.org/wiki/Green%27s_function At Citizendium* ttps://archive.today/20130101181958/http://academicearth.com/lectures/delta-function-and-greens-function MIT video lecture on Green's function* {{Authority control Differential equations Generalized functions Equations of physics Mathematical physics