Partial Differential Equation - Notes

Partial Differential Equations
Introduction
Partial Differential Equations(PDE) arise when the functions involved or
depend on two or more independent variables. Physical and Engineering
problems like solid and fluid mechanics, heat transfer, vibrations, electro-
magnetic theory and other areas lead to PDE.
Partial Differential Equations are those which involve partial
derivatives with respect to two or more independent variables.
E.g.:
∂2
u
∂x2
+
∂2
u
∂y2
= 0 Two-dimensional Laplace equation ..(1)
∂2
u
∂t2
= c2 ∂2
u
∂x2
One-dimensional Wave equation ..(2)
∂2
u
∂x2
+
∂2
u
∂y2
+
∂2
u
∂z2
= 0 Three-dimensional Laplace equation ..(3)
∂u
∂t
= c2 ∂2
u
∂x2
One-dimensional heat equation ..(4)
∂z
∂x
+
∂z
∂y
= 1 ..(5)
The ORDER of a PDE is the order of the highest derivatives in the
equation.
• NOTE: We restrict our study to PDE’s involving one dependent vari-
able z and only two independent variables x and y.
1

• NOTATIONS:
∂z
∂x
= p,
∂z
∂y
= q,
∂2
z
∂x2
= r,
∂2
z
∂x∂y
= s and
∂2
z
∂y2
= t
Ex. 1 Show that u = sin9t sin(x
4
) is a solution of a one dimensional wave
equation.
Sol. Here u = sin9t sin(x
4
).
∂2
u
∂t2
= c2 ∂2
u
∂x2
.. (1) is one dimensional wave equation.
∂u
∂t
=
∂2
u
∂t2
=
∂u
∂x
=
∂2
u
∂x2
=
Substitute above values in eq. (1), we get
2 Dept. of Mathematics, AITS - Rajkot

c =
∴ For c = , u = sin9t sin(x
4
) is a solution of a wave equation.
Ex. 2 Verify that the function u = ex
cosy is the solution of the Laplace
equation
∂2
u
∂x2
+
∂2
u
∂y2
= 0.
Sol.
Dept. of Mathematics, AITS - Rajkot 3

Ex. 3 Verify that the function u = x3
+ 3xt2
is the solution of the wave
equation
∂2
u
∂t2
= c2 ∂2
u
∂x2
for a suitable value of c.
Sol.

Exercise 1.1
Q.1 Verify the following functions are the solutions of the Laplace’s equation
∂2
u
∂x2
+
∂2
u
∂y2
= 0.
(a) u = log(x2
+ y2
)
(b) u = sinxsinhy
(c) u = tan−1 y
x
Q.2 Verify the following functions are the solutions of the wave equation
∂2
u
∂t2
= c2 ∂2
u
∂x2
(a) u = x3
+ 3xt2
(b) u = cosctsinx
Q.3 Verify the following functions are the solutions of the heat equation
∂u
∂t
= c2 ∂2
u
∂x2
(a) u = e−2t
cosx

Formation of PDE
Partial Differential equations can be formed either by the elimination of
(1) arbitrary constants present in the functional relation present in the rela-
tion between the variable
(2) arbitrary functions of these variables.
By elimination of arbitrary constants
Consider the function f(x, y, z, a, b) = 0 ..(i)
where a and b are two independent arbitrary constants. To eliminate two
constants, we require two more equations.
Differentiating eq. (i) partially with respect to x and y in turn, we obtain
∂f
∂x
+
∂f
∂z
∂z
∂x
= 0 ⇒
∂f
∂x
+ p
∂f
∂z
= 0 .. (ii)
∂f
∂y
+
∂f
∂z
∂z
∂y
= 0 ⇒
∂f
∂y
+ q
∂f
∂z
= 0 .. (iii)
Eliminating a and b from the set of equations (i), (ii) and (iii) , we get a
PDE of the first order of the form F(x, y, z, p, q) = 0. .. (iv)
Ex. 1 Eliminate the constants a and b form z = (x + a)(y + b).
Sol. Given that z = (x + a)(y + b) ... (1)
Differentiating partially eq. (1) with respect to x and y respectively,
we get
∂z
∂x
= p = ..(2)
∂z
∂y
= q = ..(3)
Eliminating a and b from equation (1), (2) and (3), we get

is the required partial differential equation.
Ex. 2 Find the differential equation of the set of all spheres whose centres
lie on the z-axis.
Sol. The equation of the spheres with centres on the z-axis is
..(1)
Differentiating partially eq. (1) with respect to x and y respectively,
we get
Eliminating arbitrary constant from (2) and (3), we get
is the required partial differential equation.

By elimination of arbitrary functions
Consider a relation between x, y and z of the type φ(u, v) = 0 ..(v)
where u and v are known functions of x, y and z and φ is an arbitrary
function of u and v.
Diﬀerentiating equ. (v) partially with respect to x and y, respectively,
we get
∂φ
∂u
∂u
∂x
+
∂u
∂z
p +
∂φ
∂v
∂v
∂x
+
∂v
∂z
p = 0 .. (vi)
∂φ
∂u
∂u
∂y
+
∂u
∂z
q +
∂φ
∂v
∂v
∂y
+
∂v
∂z
q = 0 .. (vii)
Eliminating
∂φ
∂u
and
∂φ
∂v
from the eq. (vi) and (vii), we get the
equations
∂(u, v)
∂(y, z)
p +
∂(u, v)
∂(z, x)
q =
∂(u, v)
∂(x, y)
.. (viii)
which is a PDE of the type (iv).
since the power of p and q are both unity it is also linear equation,
whereas eq. (iv) need not be linear.
Ex. 1 Eliminate the arbitrary function from the equation
z = xy + f(x2
+ y2
).
Sol. Let x2
+ y2
= u.
∴ z = xy + f(u) .. (1)
diﬀerentiating eq. (1) with respect to x and y respectively, we get

p = ..(2)
q = ..(3)
eliminating from (2) and (3), we get
Ex. 2 Eliminate arbitrary function from the equation
f(x + y + z, x2
+ y2
+ z2
) = 0.
Sol. Let x + y + z = u, x2
+ y2
+ z2
= v then
f(u, v) = 0 .. (1)
Diﬀerentiating (1) with respect to x and y, we get
∂f
∂u
∂u
∂x
+
∂u
∂z
p +
∂f
∂v
∂v
∂x
+
∂v
∂z
p = 0 .. (2)
∂f
∂u
∂u
∂y
+
∂u
∂z
q +
∂f
∂v
∂v
∂y
+
∂v
∂z
q = 0 .. (3)
Now
∂u
∂x
=
∂v
∂x
=
∂u
∂y
=
∂v
∂y
=
∂u
∂z
=
∂v
∂z
=

substituting above values in eq. (2) and (3), we get
eliminating and from above eq. (4) and (5), we get
is the required partial diﬀerential equation of the ﬁrst order.

Exercise 1.2
Q.1 Form the partial diﬀerential equation by eliminating the arbitrary
constants from the following:
1. z = (x2
+ a)(y2
+ b)
2. (x − a)2
+ (y − b)2
+ z2
= 1
Q.2 Form the partial diﬀerential equations by eliminating the arbitrary
functions from the following:
1. z = f(x2
− y2
)
2. z = x + y + f(xy)
3. f(xy + z2
, x + y + z) = 0
4. f(x2
+ y2
+ z2
, xyz) = 0

Integrals of Partial Differential Equation
• A solution or integral of a partial differential equation is a relation
between the dependent and the independent variables that satisfies
the differential equation.
• A solution which contains a number of arbitrary constants equal to
the independent variables, is called a complete integral.
• A solution obtained by giving particular values to the arbitrary
constants in a complete integral is called a particular integral.
• Singular integral
Let F(x, y, z, p, q) = 0 .. (1)
be the partial differential equation whose complete integral is
f(x, y, z, a, b) = 0 .. (2)
eliminating a, b between eq. (2) and
∂f
∂a
= 0,
∂f
∂b
= 0
if it exists, is called a singular integral.
• General Integral
In eq. (2), if we assume b = φ(a), then (2) becomes
f[x, y, z, a, φ(a)] = 0 .. (3)
differentiating (2) partially with respect to a,
∂f
∂a
+
∂f
∂b
φ (a) = 0 .. (4)
eliminating a between theses two equations (3) and (4), if it exists, is
called the general integral of eq. (1).

Solutions of PDE by the method of Direct
Integration
This method is applicable to those problems, where direct integration is
possible.
Ex. 1 Solve
∂2
z
∂x∂y
= x3
+ y3
Sol. Given that
∂
∂x
∂z
∂y
= x3
+ y3
Integrating w.r.t to keeping constant, we get
∴
∂z
∂y
=
Now integrating w.r.t. to keeping as constant
∴ z =

Ex. 2 Solve
∂2
u
∂x∂t
= e−t
cosx
Sol. Given that
∂
∂x
∂u
∂t
= e−t
cosx
Now integrating w.r.t. to keeping as constant

Ex. 3 Solve
∂3
z
∂x2∂y
= cos(2x + 3y)
Sol. Given that
∂2
∂x2
∂z
∂y
= cos(2x + 3y)
∴
∂
∂x
∂z
∂y
=
Integrating w.r.t. to keeping as constant
Finally integrating w.r.t. to keeping as constant

Lagrange’s Equation
We have
∂(u, v)
∂(y, z)
p +
∂(u, v)
∂(z, x)
q =
∂(u, v)
∂(x, y)
This can be expressed in the form Pp + Qq = R, where P, Q and R are
functions of x, y and z. This partial diﬀerential equation is known as
Lagrange’s equation.
Method to solve Pp + Qq = R
In order to solve the equation Pp + Qq = R
1 Form the subsidiary (auxiliary ) equation
dx
P
=
dy
Q
=
dz
R
2 Solve these subsidiary equations by the method of grouping or by the
method of multiples or both to get two independent solutions u = c1
and v = c2.
3 Then φ(u, v) = 0 or u = f(v) or v = f(u) is the general solution of
the equation Pp + Qq = R.
Ex. 1 Solve
y2
z
x
∂z
∂x
+ xz
∂z
∂y
= y2
.
Sol. The given equation can be written as ( in for of p and q)
y2
zp + x2
zq = xy2
comparing with Pp + Qq = R, we get
P = , Q = and R =
The subsidiary equations are
dx
P
=
dy
Q
=
dz
R
Taking ﬁrst two, we have

Now taking ﬁrst and third, we have
Ex. 2 Find the general solution of the diﬀerential equation
x2
p + y2
q = (x + y)z
Sol. Comparing with Pp + Qq = R, we get
P = , Q = and R =
The subsidiary equations are
dx
P
=
dy
Q
=
dz
R

Taking ﬁrst two, we have
Ex. 3 Solve (y + z)p + (z + x)q = x + y
Ex. 4 Solve pz − qz = z2
+ (x + y)2
Ex. 5 Solve x2
(y − z)p + y2
(z − x) = z2
(x − y)
Ex. 6 Solve (z2
− 2yz − y2
)p + (xy + zx)q = xy − zx
Exercise
1. xp + yq = z
2. xp − yq = xy
3. (1 − x)p + (2 − y)q = 3 − z
4. zxp − zyq = y2
− x2
5. (y − z)p + (z − x)q = x − y
6. p − 2q = 2x − ey
+ 1
7. x(y2
− z2
)p + y(z2
− x2
)q = z(x2
− y2
)

Special type of Nonlinear PDE of the first
order
A PDE which involves first order derivatives p and q with degree more than
one and the products of p and q is called a non-linear PDE of the first
order.
There are four standard forms of these equations.
1. Equations involving only p and q
2. Equations not involving the independent variables
3. Separable equations
4. Clairaut’s form
Standard Form 1. Equations involving only p and q
Such equations are of the form f(p,q)=0
z = ax + by + c ... (1)
is a solution of the equation f(p, q) = 0
provided f(a, b) = 0 (means put p = a and q = b) ... (2)
solving (2) for b, b = F(a)
Hence the complete integral is z = ax + F(a)y + c
where a and c are arbitrary constants.
Ex. 1 Solve pq = p + q
Sol. Here the give DE involves on p and q (so standard form 1)
The solution is
put p = and q =
therefore,
b =

Hence the complete solution is
Exercise
Solve the following equations
1. pq = 1
2. p = q2
3. p2
+ q2
= 4
4. pq + p + q = 0

Standard Form 2. Equations not involving the
independent variables
Such equations are of the form f(z,p,q)=0
Consider f(z, p, q) = 0 .. (1)
since z is a function of x and y
dz =
∂z
∂x
dx +
∂z
∂y
dy = pdx + qdy
let q = ap
then eq (1) becomes f(z, p, ap) = 0 .. (2)
solving (2) for p i.e. p = φ(z, a)
∴ dz = φ(z, a) dx + a φ(z, a) dy
∴
dz
φ(z, a)
= dx + ady
integrating, we get
dz
φ(z, a)
= x + ay + b which is a complete integral.
Ex. 1 Solve: p2
z2
+ q2
= 1
Sol. Given equation involves only p, q and z (standard form 2)
Therefore putting q = ap in given equation, we get
Now dz = pdx + qdy, substituting above values in this equation and
integrate

Ex. 2 Solve: p(1 + q) = qz
Ex. 3 Solve: z = p2
+ q2
Exercise
1 q(p2
z + q2
) = 4
2 pq = z2
3 p + q = z
4 zpq = p + q
5 z2
= 1 + p2
+ q2

Standard Form 3. Separable equations
Such equations are of the form f1(x,p) = f2(y,q)
A ﬁrst order PDE is seperable if it can be written in the form
f1(x, p) = f2(y, q)
We assume each side equal to an arbitrary constant a.
solving f1(x, p) = a ⇒ p = φ1(x, a)
solving f2(y, q) = a ⇒ q = φ2(y, a)
∴ z = φ1(x, a)dx + φ2(y, a)dy which is complete integral
Ex. 1 Solve: p − x2
= q + y2
Sol. Writing equation in the form
p − x2
= q + y2
= a
∴ p = a + x2
and q = a − y2
Now dz = pdx + qdy
dz = dx + dy
Integrating both sides, we get
z =
Ex. 2 Solve: p2
+ q2
= x2
+ y2
Sol. Writing equation in the form
p2
− x2
= y2
− q2
Let p2
− x2
= a and y2
− q2
= a
Hence, p2
= x2
+ a, q2
= y2
− a

∴ p = and q =
Now dz = pdx + qdy
dz =
Exercise
1. q − p + x − y = 0
2. p + q = x + y
3. P2
+ q2
= x + y
4. pq = xy
5. py + qx = pq
6. p + q = sinx + siny

Standard Form 4. Clairaut’s form
A ﬁrst-order PDE is said to be of Clairaut type if it can be written in the
form,
z = px + qy + f(p, q)
substitute p = a and q = b in f(p, q)
The solution of the the equation is z = ax + by + f(a, b)
Ex. 1 Solve: z = px + qy + 1 + p2 + q2
Sol. The complete integral is obtained
z = px + qy +
√
1 + a2 + b2
Ex. 2 Solve: (p + q)(z − xp − yq) = 1.
Sol.
Exercise
Solve the following equations.
1. z = px + qy + p2
q2
2. z = px + qy + 2
√
pq
3. z = px + qy +
q
p
− p
4. (1 − x)p + (2 − y)q = 3 − z
5.
z
pq
=
x
q
+
y
p
+
√
pq

Classiﬁcation of the PDE of second order
Consider the equation of the second order as
A
∂2
u
∂x2
+ B
∂2
u
∂x∂y
+ C
∂2
u
∂2y
+ f x, y, u,
∂u
∂x
,
∂u
∂y
= 0 (1)
where A is positive
Now the equation (1) is
(i) elliptic if B2
− 4AC < 0
(ii) hyperbolic if B2
− 4AC > 0
(iii) parabolic if B2
− 4AC = 0.
Exercise
Classify the following diﬀerential equations.
1 2
∂2
u
∂t2
+ 4
∂2
u
∂x∂t
+ 3
∂2
u
∂x2
= 0
2 4
∂2
u
∂t2
− 9
∂2
u
∂x∂t
+ 5
∂2
u
∂x2
= 0
3
∂2
u
∂t2
+ 4
∂2
u
∂x∂t
+ 4
∂2
u
∂x2
= 0

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Partial Differential Equation - Notes