Harmonic conjugate

For geometric conjugate points, see Projective harmonic conjugates.

In mathematics, a function $u(x,\,y)$ defined on some open domain $\Omega\subset\R^2$ is said to have as a conjugate a function $v(x,\,y)$ if and only if they are respectively real and imaginary part of a holomorphic function $f (z)$ of the complex variable $z:=x+iy\in\Omega.$ That is, $v$ is conjugated to $u$ if $f (z): = u (x, y) + i v (x, y)$ is holomorphic on $Ω.$ As a first consequence of the definition, they are both harmonic real-valued functions on $Ω$ . Moreover, the conjugate of $u,$ if it exists, is unique up to an additive constant. Also, $u$ is conjugate to $v$ if and only if $v$ is conjugate to $- u$ .

Equivalently, $v$ is conjugate to $u$ in $Ω$ if and only if $u$ and $v$ satisfy the Cauchy–Riemann equations in $Ω.$ As an immediate consequence of the latter equivalent definition, if $u$ is any harmonic function on $\Omega\subset\R^2,$ the function $u y$ is conjugate to $- u x$ , for then the Cauchy–Riemann equations are just $Δ u = 0$ and the symmetry of the mixed second order derivatives, $u x y = u y x .$ Therefore an harmonic function $u$ admits a conjugated harmonic function if and only if the holomorphic function $g (z): = u x (x, y) - i u y (x, y)$ has a primitive $f (z)$ in $Ω,$ in which case a conjugate of $u$ is, of course, $-\scriptstyle\mathrm{Im}\,f(x+iy).$ So any harmonic function always admits a conjugate function whenever its domain is simply connected, and in any case it admits a conjugate locally at any point of its domain.

There is an operator taking a harmonic function u on a simply connected region in R² to its harmonic conjugate v (putting e.g. v(x₀)=0 on a given x₀ in order to fix the indeterminacy of the conjugate up to constants). This is well known in applications as (essentially) the Hilbert transform; it is also a basic example in mathematical analysis, in connection with singular integral operators. Conjugate harmonic functions (and the transform between them) are also one of the simplest examples of a Bäcklund transform (two PDEs and a transform relating their solutions), in this case linear; more complex transforms are of interest in solitons and integrable systems.

Geometrically u and v are related as having orthogonal trajectories, away from the zeroes of the underlying holomorphic function; the contours on which u and v are constant cross at right angles. In this regard, u+iv would be the complex potential, where u is the potential function and v is the stream function.

Examples

For example, consider the function

$u(x,y)=e^x \sin y. \,$

Since

${\partial u \over \partial x } = e^x \sin y, {\partial^2 u \over \partial x^2} = e^x \sin y$

and

${\partial u \over \partial y} = e^x \cos y, {\partial^2 u \over \partial y^2} = - e^x \sin y,$

it satisfies

$\Delta u = 0.\,$

and thus is harmonic. Now suppose we have a $v (x, y)$ such that the Cauchy–Riemann equations are satisfied:

${\partial u \over \partial x} = {\partial v \over \partial y} = e^x \sin y\,$

and

${\partial u \over \partial y} = -{\partial v \over \partial x} = e^x \cos y.\,$

Simplifying,

${\partial v \over \partial y} = e^x \sin y$

and

${\partial v \over \partial x} = -e^x \cos y$

which when solved gives

$v = -e^x \cos y. \!\;$

Observe that if the functions related to u and v were interchanged, the functions would not be harmonic conjugates, since the minus sign in the Cauchy–Riemann equations makes the relationship asymmetric.

The conformal mapping property of analytic functions (at points where the derivative is not zero) gives rise to a geometric property of harmonic conjugates. Clearly the harmonic conjugate of x is y, and the lines of constant x and constant y are orthogonal. Conformality says that equally contours of constant u(x,y) and v(x,y) will also be orthogonal where they cross (away from the zeroes of f′(z)). That means that v is a specific solution of the orthogonal trajectory problem for the family of contours given by u (not the only solution, naturally, since we can take also functions of v): the question, going back to the mathematics of the seventeenth century, of finding the curves that cross a given family of non-intersecting curves at right angles.

There is an additional occurrence of the term harmonic conjugate in mathematics, and more specifically in geometry. Two points A and B are said to be harmonic conjugates of each other with respect to another pair of points C, D if (ABCD) = −1, where (ABCD) is the cross-ratio of points A, B, C, D (See Projective harmonic conjugates.)

External links

Harmonic Ratio

Categories:

Harmonic functions
Partial differential equations

Wikimedia Foundation. 2010.

Игры ⚽ Нужно решить контрольную?

Look at other dictionaries:

Harmonic function — In mathematics, mathematical physics and the theory of stochastic processes, a harmonic function is a twice continuously differentiable function f : U rarr; R (where U is an open subset of R n ) which satisfies Laplace s equation,… … Wikipedia
Conjugate Fourier series — In the mathematical field of Fourier analysis, the conjugate Fourier series arises by realizing the Fourier series formally as the boundary values of the real part of a holomorphic function on the unit disc. The imaginary part of that function… … Wikipedia
Projective harmonic conjugates — is defined by the following harmonic construction::“Given three collinear points A, B, C, let L be a point not lying on their join and let any line through C met LA, LB at M, N respectively. If AN and BM met at K , and LK meets AB at D , then D… … Wikipedia
Second harmonic generation — (SHG; also called frequency doubling) is a nonlinear optical process, in which photons interacting with a nonlinear material are effectively combined to form new photons with twice the energy, and therefore twice the frequency and half the… … Wikipedia
List of mathematics articles (H) — NOTOC H H cobordism H derivative H index H infinity methods in control theory H relation H space H theorem H tree Haag s theorem Haagerup property Haaland equation Haar measure Haar wavelet Haboush s theorem Hackenbush Hadamard code Hadamard… … Wikipedia
Conjugation — Conjugal redirects here. For the type of prison visit, see conjugal visit. Conjugation may refer to: Grammatical conjugation, the modification of a verb from its basic form Marriage, a relationship between two or more individuals Contents 1… … Wikipedia
Hilbert transform — In mathematics and in signal processing, the Hilbert transform is a linear operator which takes a function, u ( t ), and produces a function, H ( u )( t ), with the same domain. The Hilbert transform is named after David Hilbert, who first… … Wikipedia
Cross-ratio — D is the harmonic conjugate of C with respect to A and B In geometry, the cross ratio, also called double ratio and anharmonic ratio, is a special number associated with an ordered quadruple of collinear points, particularly points on a… … Wikipedia
List of complex analysis topics — Complex analysis, traditionally known as the theory of functions of a complex variable, is the branch of mathematics that investigates functions of complex numbers. It is useful in many branches of mathematics, including number theory and applied … Wikipedia
Orthogonal trajectory — In mathematics, orthogonal trajectories are a family of curves in the plane that intersect a given family of curves at right angles. The problem is classical, but is now understood by means of complex analysis; see for example harmonic conjugate … Wikipedia

Academic Dictionaries and Encyclopedias

Harmonic conjugate

Examples

External links

Look at other dictionaries:

Share the article and excerpts

Academic Dictionaries and Encyclopedias

Wikipedia

Harmonic conjugate

Examples

External links

Look at other dictionaries:

Share the article and excerpts

Direct link