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Homedifferential equation
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differential equation
A differential equation is an equation involving an unknown function of one or more variables, its derivatives and the independent variables. This type of equations comes up often in many different branches of mathematics. They are also especially important in many problems in physics and engineering.
There are many types of differential equations. An ordinary differential equation (ODE) is a differential equation where the unknown function depends on a single variable. A general ODE has the form
$F(x,f(x),f^{{\prime}}(x),\ldots,f^{{(n)}}(x))=0,$  (1) 
where the unknown $f$ is usually understood to be a real or complex valued function of $x$, and $x$ is usually understood to be either a real or complex variable. The order of a differential equation is the order of the highest derivative appearing in Eq. (1). In this case, assuming that $F$ depends nontrivially on $f^{{(n)}}(x)$, the equation is of $n$th order.
If a differential equation is satisfied by a function which identically vanishes (i.e. $f(x)=0$ for each $x$ in the domain of interest), then the equation is said to be homogeneous. Otherwise it is said to be nonhomogeneous (or inhomogeneous). Many differential equations can be expressed in the form
$L[f]=g(x),$ 
where $L$ is a differential operator (with $g(x)=0$ for the homogeneous case). If the operator $L$ is linear in $f$, then the equation is said to be a linear ODE and otherwise nonlinear.
Other types of differential equations involve more complicated relations involving the unknown function. A partial differential equation (PDE) is a differential equation where the unknown function depends on more than one variable. In a delay differential equation (DDE), the unknown function depends on the state of the system at some instant in the past.
Solving differential equations is a difficult task. Three major types of approaches are possible:

Exact methods are generally restricted to equations of low order and/or to linear systems.

Qualitative methods do not give explicit formula for the solutions, but provide information pertaining to the asymptotic behavior of the system.

Finally, numerical methods allow to construct approximated solutions.
Examples
A common example of an ODE is the equation for simple harmonic motion
$\frac{d^{2}u}{dx^{2}}+ku=0.$ 
This equation is of second order. It can be transformed into a system of two first order differential equations by introducing a variable $v=du/dx$. Indeed, we then have
$\displaystyle\frac{dv}{dx}$  $\displaystyle=ku$  
$\displaystyle\frac{du}{dx}$  $\displaystyle=v.$ 
A common example of a PDE is the wave equation in three dimensions
$\frac{\partial^{2}u}{\partial x^{2}}+\frac{\partial^{2}u}{\partial y^{2}}+% \frac{\partial^{2}u}{\partial z^{2}}=c^{2}\frac{\partial^{2}u}{\partial t^{2}}$ 
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Comments
Generalization
I would like to add a discussion of some very
general conditions under which differential
equations can be constructed (and how ODE's
and PDE's can be lumped under the same general
definition).
However, I'm not familiar with differential
equations in abstract spaces. If anyone can
point out some references I'm willing to
investigate this. Also if anyone is already
familiar with this subject and would like
to make an addition to this article I'm willing
to put them in the ACL list.