In mathematics, a system of differential equations is a finite set of differential equations. Such a system can be either linear or non-linear. Also, such a system can be either a system of ordinary differential equations or a system of partial differential equations.
See main article: Linear differential equation.
See also: Matrix differential equation.
A first-order linear system of ODEs is a system in which every equation is first order and depends on the unknown functions linearly. Here we consider systems with an equal number of unknown functions and equations. These may be written as
| dxj | |
| dt |
=aj1(t)x1+\ldots+ajn(t)xn+gj(t), j=1,\ldots,n
where
n
aji(t),gj(t)
| d | |
| dt |
\begin{bmatrix}x1\ x2\ \vdots\ xn\end{bmatrix}=\begin{bmatrix}a11&\ldots&a1n\ a21&\ldots&a2\ \vdots&\ldots&\vdots\ an1&&an\end{bmatrix}\begin{bmatrix}x1\ x2\ \vdots\ xn\end{bmatrix}+\begin{bmatrix}g1\ g2\ \vdots\ gn\end{bmatrix},
or simply
|
=A(t)x(t)+g(t)
A linear system is said to be homogeneous if
gj(t)=0
j
t
| x1,\ldots |
| ,xp |
C1
| x1+ |
\ldots+Cp
| xp |
C1,\ldots,Cp
The case where the coefficients
aji(t)
x=C1
| λ1t | |
| v1e |
+\ldots+Cn
| λnt | |
| vne |
λi
A
vi
1\leqi\leqn
A
For an arbitrary system of ODEs, a set of solutions
| x1(t), |
\ldots
| ,xn(t) |
| C | ||
|
+\ldots+Cn
| xn |
=0 \forallt
C1=\ldots=Cn=0
A second-order differential equation
\ddot{x}=f(t,x,
| x |
)
| y=x |
\begin{cases}
| x |
&=&y\
| y |
&=&f(t,x,y)\end{cases}
Just as with any linear system of two equations, two solutions may be called linearly-independent if
C1x1+C2x2=0
C1=C2=0
\begin{vmatrix}x1&x2\
| x |
1&
| x |
2\end{vmatrix}
Like any system of equations, a system of linear differential equations is said to be overdetermined if there are more equations than the unknowns. For an overdetermined system to have a solution, it needs to satisfy the compatibility conditions.[1] For example, consider the system:
| \partialu | |
| \partialxi |
=fi,1\lei\lem.
| \partialfi | |
| \partialxk |
-
| \partialfk | |
| \partialxi |
=0,1\lei,k\lem.
See also: Cauchy problem and Ehrenpreis's fundamental principle.
Perhaps the most famous example of a nonlinear system of differential equations is the Navier–Stokes equations. Unlike the linear case, the existence of a solution of a nonlinear system is a difficult problem (cf. Navier–Stokes existence and smoothness.)
Other examples of nonlinear systems of differential equations include the Lotka–Volterra equations.
See also: h-principle.
A differential system is a means of studying a system of partial differential equations using geometric ideas such as differential forms and vector fields.
For example, the compatibility conditions of an overdetermined system of differential equations can be succinctly stated in terms of differential forms (i.e., for a form to be exact, it needs to be closed). See integrability conditions for differential systems for more.