Differential equation: Difference between revisions
imported>Greg Woodhouse (added Lorenz system as nonlinear example) |
imported>Greg Woodhouse (added heat equation as example and corrected definition of PDE) |
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The [[Schrödinger equation]] is fundamental in [[quantum mechanics]]. It is given by | The [[Schrödinger equation]] is fundamental in [[quantum mechanics]]. It is given by | ||
:<math> i\hbar \frac{\partial\psi(x,t)}{\partial t} = - \frac{\hbar^2}{2m} \frac{\partial^2 \psi(x,t)}{\partial x^2}. </math> | :<math> i\hbar \frac{\partial\psi(x,t)}{\partial t} = - \frac{\hbar^2}{2m} \frac{\partial^2 \psi(x,t)}{\partial x^2}. </math> | ||
Another example of a partial differential eqauation (or PDE) is the [[heat equation]] | |||
:<math>\frac{\partial u}{\partial t} = -k (\frac{\partial^2 u}{\partial^2 x} +\frac{\partial^2 u}{\partial^2 y})</math> | |||
The reason that these two equations (the [[Schrödinger equation]] and the [[heat equation]]) are called [[partial differential equation]]s is that the unknown (<math>\psi</math> in the Schrödinger equation, and u in the heat equation) depends on multiple variables, and the equation involves [[partial derivative]]s with respect to these variables. | |||
The ''order'' of a differential equation is that of the highest derivative that it contains. For instance, the equation | The ''order'' of a differential equation is that of the highest derivative that it contains. For instance, the equation | ||
:<math> \frac{du(t)}{dt} = u(t) </math> | :<math> \frac{du(t)}{dt} = u(t) </math> | ||
is a first-order differential equation, while the Schrödinger equation | is a first-order differential equation, while the Schrödinger equation and heat equation are examples of second order equations. | ||
[[Category:Mathematics Workgroup]] | [[Category:Mathematics Workgroup]] | ||
[[Category:CZ Live]] | [[Category:CZ Live]] | ||
Revision as of 11:51, 2 April 2007
In mathematics, a differential equation is an equation relating a function and its derivatives. Many of the fundamental laws of physics, chemistry, biology and economics can be formulated as differential equations. The question then becomes how to find the solutions of those equations.
The mathematical theory of differential equations has developed together with the sciences where the equations originate and where the results find application. Diverse scientific fields often give rise to identical problems in differential equations. In such cases, the mathematical theory can unify otherwise quite distinct scientific fields. A celebrated example is Fourier's theory of the conduction of heat in terms of sums of trigonometric functions, Fourier series, which finds application in the propagation of sound, the propagation of electric and magnetic fields, radio waves, optics, elasticity, spectral analysis of radiation, and other scientific fields.
Examples
A simple differential equation is
This equation is satisfied by any function which equals its derivative. One of the solutions of this equation is .
Nonlinear equations and systems of equations frequently occur in the study of physical systems. An important example of a nonlinear oscillator is the Lorenz System
This is a basic example of a system with chaotic behavior.
The Schrödinger equation is fundamental in quantum mechanics. It is given by
Another example of a partial differential eqauation (or PDE) is the heat equation
The reason that these two equations (the Schrödinger equation and the heat equation) are called partial differential equations is that the unknown ( in the Schrödinger equation, and u in the heat equation) depends on multiple variables, and the equation involves partial derivatives with respect to these variables.
The order of a differential equation is that of the highest derivative that it contains. For instance, the equation
is a first-order differential equation, while the Schrödinger equation and heat equation are examples of second order equations.