In mathematics, a first-order partial differential equation is a partial differential equation that involves only first derivatives of the unknown function of n variables. The equation takes the form
F(x1,\ldots,xn,u,u
| x1 |
,\ldots
| u | |
| xn |
)=0.
Such equations arise in the construction of characteristic surfaces for hyperbolic partial differential equations, in the calculus of variations, in some geometrical problems, and in simple models for gas dynamics whose solution involves the method of characteristics. If a family of solutionsof a single first-order partial differential equation can be found, then additional solutions may be obtained by forming envelopes of solutions in that family. In a related procedure, general solutions may be obtained by integrating families of ordinary differential equations.
The general solution to the first order partial differential equation is a solution which contains an arbitrary function. But, the solution to the first order partial differential equations with as many arbitrary constants as the number of independent variables is called the complete integral. The following n-parameter family of solutions
\phi(x1,x2,...,xn,u,a1,a2,...,an)
is a complete integral if
| det|\phi | |
| xiaj |
| ≠ 0
The solutions are described in relatively simple manner in two or three dimensions with which the key concepts are trivially extended to higher dimensions. A general first-order partial differential equation in three dimensions has the form
F(x,y,z,u,p,q,r)=0,
where
p=ux,q=uy,r=uz.
\phi(x,y,z,u,a,b,c)=0
(a,b,c)
\phix+p\phiu=0
\phiy+q\phiu=0
\phiz+r\phiu=0
Along with the complete integral
\phi=0
(x,y,z,u,p,q,r)
u=\sqrt{(x-a)2+(y-b)2}+z-c
p2+q2=1
r=1
Once a complete integral is found, a general solution can be constructed from it. The general integral is obtained by making the constants functions of the coordinates, i.e.,
a=a(x,y,z),b=b(x,y,z),c=c(x,y,z)
(p,q,r)
\phix+p\phiu=-(ax\phia+bx\phib+cx\phic)
\phiy+q\phiu=-(ay\phia+by\phib+cy\phic)
\phiz+r\phiu=-(az\phia+bz\phib+cz\phic)
in which we require the right-hand side terms of all the three equations to vanish identically so that elimination of
(a,b,c)
\phi
J\phia=0, J\phib=0, J\phic=0
where
| J= | \partial(a,b,c) |
| \partial(x,y,z) |
=\begin{align} \begin{vmatrix}ax&ay&az\ bx&by&bz\ cx&cy&cz\end{vmatrix}\end{align}
is the Jacobian determinant. The condition
J=0
J=0
(a,b,c)
c=\psi(a,b).
Once
(a,b)
dc=\psiada+\psibdb
(ax\phia+bx\phib+cx\phic)=0
(ay\phia+by\phib+cy\phic)=0
(az\phia+bz\phib+cz\phic)=0
\phiada+\phibdb+\phicdc=0
dc
(\phia+\phic\psia)da+(\phib+\phic\psib)db=0
Since
a
b
(\phia+\phic\psia)=0
(\phib+\phic\psib)=0.
The above two equations can be used to solve
a
b
(a,b,c)
\phi=0
(x,y,z,u)
(a,b)
\psi(a,b)
c=\psi(a,b)
J
c=\psi(a)
c=\psi(b)
Singular integral is obtained when
J ≠ 0
(a,b,c)
\phi=0
\phia=0, \phib=0, \phic=0.
The three equations can be used to solve the three unknowns
(a,b,c)
(a,b,c)
Usually, most integrals fall into three categories defined above, but it may happen that a solution does not fit into any of three types of integrals mentioned above. These solutions are called special integrals. A relation
\chi(x,y,z,u)=0
(a,b,c)
\phix\chiu-\chix\phiu=0
\phiy\chiu-\chiy\phiu=0
\phiz\chiu-\chiz\phiu=0.
If we able to determine
(a,b,c)
\chi=0
The complete integral in two-dimensional space can be written as
\phi(x,y,u,a,b)=0
a
\phi(x,y,z,a,\psi(a))=0, \phia+\psia\phib=0.
The singular integral if it exists can be obtained by eliminating
(a,b)
\phi(x,y,z,a,b)=0, \phia=0, \phib=0.
If a complete integral is not available, solutions may still be obtained by solving a system of ordinary equations. To obtain this system, first note that the PDE determines a cone (analogous to the light cone) at each point: if the PDE is linear in the derivatives of u (it is quasi-linear), then the cone degenerates into a line. In the general case, the pairs (p,q) that satisfy the equation determine a family of planes at a given point:
u-u0=p(x-x0)+q(y-y0),
where
F(x0,y0,u0,p,q)=0.
The envelope of these planes is a cone, or a line if the PDE is quasi-linear. The condition for an envelope is
Fpdp+Fqdq=0,
where F is evaluated at
(x0,y0,u0,p,q)
dx:dy:du=Fp:Fq:(pFp+qFq).
This direction corresponds to the light rays for the wave equation.To integrate differential equations along these directions, we require increments for p and q along the ray. This can be obtained by differentiating the PDE:
Fx+Fup+Fppx+Fqpy=0,
Fy+Fuq+Fpqx+Fqqy=0,
Therefore the ray direction in
(x,y,u,p,q)
dx:dy:du:dp:dq=Fp:Fq:(pFp+qFq):(-Fx-Fup):(-Fy-Fuq).
The integration of these equations leads to a ray conoid at each point
(x0,y0,u0)
This part can be referred to
\S1.2.3
An equivalent description is given. Two definitions of linear dependence are given for first-order linear partial differential equations.
(*) \left\{{\begin{array}{*{20}{c}}
| \sum\limits | |
| ij |
| (1) | |
| {a | |
| ij |
\dfrac{{\partial{yj}}}{{\partial{xi}}}}+{f1}=0\\ \vdots\\
| \sum\limits | |
| ij |
| (n) | |
| {a | |
| ij |
\dfrac{{\partial{yj}}}{{\partial{xi}}}}+{fn}=0 \end{array}}\right.
xi
yj
| (k) | |
| a | |
| ij |
fk
Definition I: Given a number field
P
ck\inP
Definition II (differential linear dependence): Given a number field
P
{ck},dkl\inP
{dkl
The div-curl systems, Maxwell's equations, Einstein's equations (with four harmonic coordinates) and Yang-Mills equations (with gauge conditions) are well-determined in definition II, whereas are over-determined in definition I.
Characteristic surfaces for the wave equation are level surfaces for solutions of the equation
| 2 | |
| u | |
| t |
=c2
| 2 | |
| \left(u | |
| x |
| 2 | |
| +u | |
| y |
+
| 2 | |
| u | |
| z |
\right).
There is little loss of generality if we set
ut=1
| 2 | |
| u | |
| x |
+
| 2 | |
| u | |
| y |
+
| 2= | |
| u | |
| z |
| 1 | |
| c2 |
.
In vector notation, let
\vecx=(x,y,z) \hbox{and} \vecp=(ux,uy,uz).
A family of solutions with planes as level surfaces is given by
u(\vecx)=\vecp ⋅ (\vecx-\vec{x0}),
where
|\vecp|=
| 1 | |
| c |
, and \vec{x0} isarbitrary.
If x and x0 are held fixed, the envelope of these solutions is obtained by finding a point on the sphere of radius 1/c where the value of u is stationary. This is true if
\vecp
\vecx-\vec{x0}
u(\vecx)=\pm
| 1 | |
| c |
|\vecx-\vec{x0}|.
These solutions correspond to spheres whose radius grows or shrinks with velocity c. These are light cones in space-time.
The initial value problem for this equation consists in specifying a level surface S where u=0 for t=0. The solution is obtained by taking the envelope of all the spheres with centers on S, whose radii grow with velocity c. This envelope is obtained by requiring that
| 1 | |
| c |
|\vecx-\vec{x0}| \hbox{isstationaryfor} \vec{x0}\inS.
This condition will be satisfied if
|\vecx-\vec{x0}|
. Lawrence C. Evans . Partial Differential Equations . American Mathematical Society . Providence . 1998 . 0-8218-0772-2 .
. R. . Courant. Richard Courant. amp . D. . Hilbert. David Hilbert. Methods of Mathematical Physics: Partial Differential Equations . II . Wiley-Interscience . New York . 1962 . 9783527617241.