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Page 1
Basic Theory of Linear O.D.E.’s
Definition: A linear O.D.E. of order n, in the independent variable x and the dependent
variable y is an equation that can be expressed in the form:
a
0
(x)y
n ( )
+a
1
(x)y
n!1 ( )
+.....+a
n!1
(x) " y +a
n
(x)y =b(x)
We will assume that a
0
(x), a
1
(x), …. , a
n
(x) and b(x) are continuous real-valued functions
on the interval [a, b] and a
0
(x) ? 0 for at least one x in [a, b].
Remark: A linear ODE satisfies the following conditions:
1- The dependent variable y and its derivatives occur to the first degree only.
2- No products of y and/or any of its derivatives appear in the equation.
3- No transcendental functions of y and/or its derivatives occur.
Definition: Equations that not satisfy the above conditions are called nonlinear.
Remark:
1) The functions a
0
(x), a
1
(x), …. , a
n
(x) are called the coefficients of the equation.
2) The right-hand member b(x) is called the non-homogeneous term.
3) If b(x) = 0, then the equation reduces to
a
0
(x)y
n ( )
+a
1
(x)y
n!1 ( )
+.....+a
n!1
(x) " y +a
n
(x)y =0
and it is called a homogeneous linear differential equation (H.L.D.E.).
Example:
1)
d
3
y
dx
3
!cos(x)
d
2
y
dx
2
+3x
dy
dx
+x
3
y=e
x
is a linear differential equation of order 3,
where a
0
(x) = 1, a
2
(x) = - cos(x), a
3
(x) = 3x, a
4
(x) = x
3
and b(x) = e
x
, they are all
continuous function on
! .
Definition: If a
0
, a
1
, …. , a
n
are all constants, then we have a linear differential equation
with constant coefficients, otherwise we have an equation with variable coefficients.
Example:
1) 3y’’’ + 2y’’ – 4y’ – 7y = sin x is an equation with constant coefficients.
2) 2y’’ + xy’ – e
x
y = 0 is an equation with variable coefficients.
Theorem: Let
a
0
(x)y
n ( )
+a
1
(x)y
n!1 ( )
+.....+a
n!1
(x) " y +a
n
(x)y =b(x)
with a
0
(x), a
1
(x), …. , a
n
(x) and b(x) are continuous real-valued functions on the interval
[a, b] and a
0
(x) ? 0 for at least one x in [a, b].
Let x
0
be a point on the interval [a, b] and let c
0
, c
1
, c
n-1
be n arbitrary constants.
Conclusion:
There exists a unique function f(x) defined on [a, b] such that f(x) is a solution of the
linear differential equation and satisfies
f(x
0
) = c
0
, f’(x
0
) = c
1
, f’’(x
0
) = c
2
, … , f
(n-1)
(x
0
) = c
n-1
.
Page 2
Basic Theory of Linear O.D.E.’s
Definition: A linear O.D.E. of order n, in the independent variable x and the dependent
variable y is an equation that can be expressed in the form:
a
0
(x)y
n ( )
+a
1
(x)y
n!1 ( )
+.....+a
n!1
(x) " y +a
n
(x)y =b(x)
We will assume that a
0
(x), a
1
(x), …. , a
n
(x) and b(x) are continuous real-valued functions
on the interval [a, b] and a
0
(x) ? 0 for at least one x in [a, b].
Remark: A linear ODE satisfies the following conditions:
1- The dependent variable y and its derivatives occur to the first degree only.
2- No products of y and/or any of its derivatives appear in the equation.
3- No transcendental functions of y and/or its derivatives occur.
Definition: Equations that not satisfy the above conditions are called nonlinear.
Remark:
1) The functions a
0
(x), a
1
(x), …. , a
n
(x) are called the coefficients of the equation.
2) The right-hand member b(x) is called the non-homogeneous term.
3) If b(x) = 0, then the equation reduces to
a
0
(x)y
n ( )
+a
1
(x)y
n!1 ( )
+.....+a
n!1
(x) " y +a
n
(x)y =0
and it is called a homogeneous linear differential equation (H.L.D.E.).
Example:
1)
d
3
y
dx
3
!cos(x)
d
2
y
dx
2
+3x
dy
dx
+x
3
y=e
x
is a linear differential equation of order 3,
where a
0
(x) = 1, a
2
(x) = - cos(x), a
3
(x) = 3x, a
4
(x) = x
3
and b(x) = e
x
, they are all
continuous function on
! .
Definition: If a
0
, a
1
, …. , a
n
are all constants, then we have a linear differential equation
with constant coefficients, otherwise we have an equation with variable coefficients.
Example:
1) 3y’’’ + 2y’’ – 4y’ – 7y = sin x is an equation with constant coefficients.
2) 2y’’ + xy’ – e
x
y = 0 is an equation with variable coefficients.
Theorem: Let
a
0
(x)y
n ( )
+a
1
(x)y
n!1 ( )
+.....+a
n!1
(x) " y +a
n
(x)y =b(x)
with a
0
(x), a
1
(x), …. , a
n
(x) and b(x) are continuous real-valued functions on the interval
[a, b] and a
0
(x) ? 0 for at least one x in [a, b].
Let x
0
be a point on the interval [a, b] and let c
0
, c
1
, c
n-1
be n arbitrary constants.
Conclusion:
There exists a unique function f(x) defined on [a, b] such that f(x) is a solution of the
linear differential equation and satisfies
f(x
0
) = c
0
, f’(x
0
) = c
1
, f’’(x
0
) = c
2
, … , f
(n-1)
(x
0
) = c
n-1
.
Remark: The theorem extends the I.V.P. discussed for first order differential equations
to linear differential equations of order n.
Example:
Consider the I.V.P.
d
2
y
dx
2
+3x
dy
dx
+x
3
y=e
x
y(1)=2
y'(1)= !5
"
#
$
$
%
$
$
a
0
(x) = 1, a
1
(x) = 3x, a
3
(x) = x
3
, and b(x) = e
x
, they are continuous functions everywhere.
We have a linear differential equation order 2. The real numbers c
0
= 2 and c
1
= -5.
Then, according to the theorem there exists an unique function f(x) continuous
everywhere that is the solution of the equation and f(1) = 2 and f(x) = -5.
Corollary: Given the H.L.D.E.
a
0
(x)y
n ( )
+a
1
(x)y
n!1 ( )
+.....+a
n!1
(x) " y +a
n
(x)y =0
with a
0
(x), a
1
(x), …. , a
n
(x) are continuous real-valued functions on the interval [a, b] and
a
0
(x) ? 0 for at least one x in [a, b].
Let f(x) be a solution of the H.L.D.E. such that f(x
0
) = 0, f’(x
0
) = 0, f’’(x
0
) = 0, … ,
f
(n-1)
(x
0
) = 0 where x
0
is in [a, b],
Conclusion:
f(x) = 0 for all x in [a, b].
Example:
y’’’ + 2y’’ + 4xy’ + x
2
y = 0
y(2) = y’(2) = y’’(2) = 0
The unique solution that satisfies the I.V.P. is f(x) = 0
Definition: Given k functions defined on an interval [a, b], f
1
(x), f
2
(x), … , f
k
(x), and k
constants, c
1
, c
2
, … , c
k
. The expression
c
1
f
1
(x) + c
2
f
2
(x) + … + c
k
f
k
(x)
is called a linear combination of f
1
(x), f
2
(x), … , f
k
(x).
Basic Theorem on Homogeneous Linear Differential Equations
Given the n-th order H.L.D.E.
a
0
(x)y
n ( )
+a
1
(x)y
n!1 ( )
+.....+a
n!1
(x) " y +a
n
(x)y =0
let f
1
(x), f
2
(x), … , f
k
(x) be k solutions of the H.L.D.E. on the interval [a, b].
Conclusion:
The linear combination c
1
f
1
(x) + c
2
f
2
(x) + … + c
k
f
k
(x) is a solution of H.L.D.E. on
[a, b] where c
1
, c
2
, … , c
k
are k arbitrary constants.
Example:
Page 3
Basic Theory of Linear O.D.E.’s
Definition: A linear O.D.E. of order n, in the independent variable x and the dependent
variable y is an equation that can be expressed in the form:
a
0
(x)y
n ( )
+a
1
(x)y
n!1 ( )
+.....+a
n!1
(x) " y +a
n
(x)y =b(x)
We will assume that a
0
(x), a
1
(x), …. , a
n
(x) and b(x) are continuous real-valued functions
on the interval [a, b] and a
0
(x) ? 0 for at least one x in [a, b].
Remark: A linear ODE satisfies the following conditions:
1- The dependent variable y and its derivatives occur to the first degree only.
2- No products of y and/or any of its derivatives appear in the equation.
3- No transcendental functions of y and/or its derivatives occur.
Definition: Equations that not satisfy the above conditions are called nonlinear.
Remark:
1) The functions a
0
(x), a
1
(x), …. , a
n
(x) are called the coefficients of the equation.
2) The right-hand member b(x) is called the non-homogeneous term.
3) If b(x) = 0, then the equation reduces to
a
0
(x)y
n ( )
+a
1
(x)y
n!1 ( )
+.....+a
n!1
(x) " y +a
n
(x)y =0
and it is called a homogeneous linear differential equation (H.L.D.E.).
Example:
1)
d
3
y
dx
3
!cos(x)
d
2
y
dx
2
+3x
dy
dx
+x
3
y=e
x
is a linear differential equation of order 3,
where a
0
(x) = 1, a
2
(x) = - cos(x), a
3
(x) = 3x, a
4
(x) = x
3
and b(x) = e
x
, they are all
continuous function on
! .
Definition: If a
0
, a
1
, …. , a
n
are all constants, then we have a linear differential equation
with constant coefficients, otherwise we have an equation with variable coefficients.
Example:
1) 3y’’’ + 2y’’ – 4y’ – 7y = sin x is an equation with constant coefficients.
2) 2y’’ + xy’ – e
x
y = 0 is an equation with variable coefficients.
Theorem: Let
a
0
(x)y
n ( )
+a
1
(x)y
n!1 ( )
+.....+a
n!1
(x) " y +a
n
(x)y =b(x)
with a
0
(x), a
1
(x), …. , a
n
(x) and b(x) are continuous real-valued functions on the interval
[a, b] and a
0
(x) ? 0 for at least one x in [a, b].
Let x
0
be a point on the interval [a, b] and let c
0
, c
1
, c
n-1
be n arbitrary constants.
Conclusion:
There exists a unique function f(x) defined on [a, b] such that f(x) is a solution of the
linear differential equation and satisfies
f(x
0
) = c
0
, f’(x
0
) = c
1
, f’’(x
0
) = c
2
, … , f
(n-1)
(x
0
) = c
n-1
.
Remark: The theorem extends the I.V.P. discussed for first order differential equations
to linear differential equations of order n.
Example:
Consider the I.V.P.
d
2
y
dx
2
+3x
dy
dx
+x
3
y=e
x
y(1)=2
y'(1)= !5
"
#
$
$
%
$
$
a
0
(x) = 1, a
1
(x) = 3x, a
3
(x) = x
3
, and b(x) = e
x
, they are continuous functions everywhere.
We have a linear differential equation order 2. The real numbers c
0
= 2 and c
1
= -5.
Then, according to the theorem there exists an unique function f(x) continuous
everywhere that is the solution of the equation and f(1) = 2 and f(x) = -5.
Corollary: Given the H.L.D.E.
a
0
(x)y
n ( )
+a
1
(x)y
n!1 ( )
+.....+a
n!1
(x) " y +a
n
(x)y =0
with a
0
(x), a
1
(x), …. , a
n
(x) are continuous real-valued functions on the interval [a, b] and
a
0
(x) ? 0 for at least one x in [a, b].
Let f(x) be a solution of the H.L.D.E. such that f(x
0
) = 0, f’(x
0
) = 0, f’’(x
0
) = 0, … ,
f
(n-1)
(x
0
) = 0 where x
0
is in [a, b],
Conclusion:
f(x) = 0 for all x in [a, b].
Example:
y’’’ + 2y’’ + 4xy’ + x
2
y = 0
y(2) = y’(2) = y’’(2) = 0
The unique solution that satisfies the I.V.P. is f(x) = 0
Definition: Given k functions defined on an interval [a, b], f
1
(x), f
2
(x), … , f
k
(x), and k
constants, c
1
, c
2
, … , c
k
. The expression
c
1
f
1
(x) + c
2
f
2
(x) + … + c
k
f
k
(x)
is called a linear combination of f
1
(x), f
2
(x), … , f
k
(x).
Basic Theorem on Homogeneous Linear Differential Equations
Given the n-th order H.L.D.E.
a
0
(x)y
n ( )
+a
1
(x)y
n!1 ( )
+.....+a
n!1
(x) " y +a
n
(x)y =0
let f
1
(x), f
2
(x), … , f
k
(x) be k solutions of the H.L.D.E. on the interval [a, b].
Conclusion:
The linear combination c
1
f
1
(x) + c
2
f
2
(x) + … + c
k
f
k
(x) is a solution of H.L.D.E. on
[a, b] where c
1
, c
2
, … , c
k
are k arbitrary constants.
Example:
Given the H.L.D.E.
d
2
y
dx
2
+y=0 ,
The functions f
1
(x) = sin x and f
2
(x) = cos x are solutions of the equation, since taking
the second derivative of the function f
1
''
(x)=!sin!x and substituting into the equation,
we get: –sin x + sin x = 0. Similarly for the other function.
Then g(x) = c
1
sin x + c
2
cos x is a solution of the equation where c
1
and c
2
are any
arbitrary constant: g’’(x) = - c
1
sinx – c
2
cos x, substituting into the equation we get
- c
1
sinx – c
2
cos x + c
1
sinx + c
2
cos x = 0.
Definition: n functions defined on an interval [a, b], f
1
(x), f
2
(x), … , f
n
(x) are called
linearly dependent on [a, b] if there exist constants c
1
, c
2
, … , c
n
, not all of them zero,
such that the linear combination
c
1
f
1
(x) + c
2
f
2
(x) + … + c
n
f
n
(x) = 0
for all x in [a, b].
Example:
1) The functions f
1
(x) = x
2
and f
2
(x) = 4x
2
are linearly dependent on [-1, 1] since
there exist constants c
1
= - 4 and c
2
= 1 such that c
1
f
1
(x) + c
2
f
2
(x) = -4x
2
+ 4x
2
= 0 for all
x in [-1, 1].
2) The functions f
1
(x) = e
x
, f
2
(x) = - e
x
and f
3
(x) = 8e
x
are linearly dependent on [-10, 10]
since there exist constants c
1
= 5, c
2
= 1 and c
3
= 1 such that
c
1
f
1
(x) + c
2
f
2
(x) + c
3
f
3
(x) = 5e
x
– e
x
+ 4e
x
= 0 for all x in [-10, 10].
Definition: n functions defined on an interval [a, b], f
1
(x), f
2
(x), … , f
n
(x) are called
linearly independent on [a, b] if they are NOT linear dependent on [a, b].
This means that f
1
(x), f
2
(x), … , f
n
(x) are linearly independent on [a, b] if the relation
c
1
f
1
(x) + c
2
f
2
(x) + … + c
n
f
n
(x) = 0 for all x in [a, b]
implies that c
1
= c
2
= … = c
n
= 0.
Example:
The functions f
1
(x) = x
2
, f
2
(x) = x
3
and f
3
(x) = x
5
are linearly independent on [-5, 5] since
the relation
c
1
f
1
(x) + c
2
f
2
(x) + c
3
f
3
(x) = c
1
x
2
+ c
2
x
3
+ c
3
x
5
= 0 for all x in [-5, 5]
if and only if c
1
= c
2
= c
3
= 0.
Theorem: The n-th order H.L.D.E.
a
0
(x)y
n ( )
+a
1
(x)y
n!1 ( )
+.....+a
n!1
(x) " y +a
n
(x)y =0
always possesses n solutions f
1
(x), f
2
(x), … , f
n
(x) that are linearly independent.
Furthermore, if f
1
(x), f
2
(x), … , f
n
(x) are n linearly independent solutions of the equation,
then every solution f(x) of the equation can be expressed as a linear combination
f(x) = c
1
f
1
(x) + c
2
f
2
(x) + … + c
n
f
n
(x)
of those n solutions by a proper choice of constants c
1
, c
2
, … , c
n
.
Page 4
Basic Theory of Linear O.D.E.’s
Definition: A linear O.D.E. of order n, in the independent variable x and the dependent
variable y is an equation that can be expressed in the form:
a
0
(x)y
n ( )
+a
1
(x)y
n!1 ( )
+.....+a
n!1
(x) " y +a
n
(x)y =b(x)
We will assume that a
0
(x), a
1
(x), …. , a
n
(x) and b(x) are continuous real-valued functions
on the interval [a, b] and a
0
(x) ? 0 for at least one x in [a, b].
Remark: A linear ODE satisfies the following conditions:
1- The dependent variable y and its derivatives occur to the first degree only.
2- No products of y and/or any of its derivatives appear in the equation.
3- No transcendental functions of y and/or its derivatives occur.
Definition: Equations that not satisfy the above conditions are called nonlinear.
Remark:
1) The functions a
0
(x), a
1
(x), …. , a
n
(x) are called the coefficients of the equation.
2) The right-hand member b(x) is called the non-homogeneous term.
3) If b(x) = 0, then the equation reduces to
a
0
(x)y
n ( )
+a
1
(x)y
n!1 ( )
+.....+a
n!1
(x) " y +a
n
(x)y =0
and it is called a homogeneous linear differential equation (H.L.D.E.).
Example:
1)
d
3
y
dx
3
!cos(x)
d
2
y
dx
2
+3x
dy
dx
+x
3
y=e
x
is a linear differential equation of order 3,
where a
0
(x) = 1, a
2
(x) = - cos(x), a
3
(x) = 3x, a
4
(x) = x
3
and b(x) = e
x
, they are all
continuous function on
! .
Definition: If a
0
, a
1
, …. , a
n
are all constants, then we have a linear differential equation
with constant coefficients, otherwise we have an equation with variable coefficients.
Example:
1) 3y’’’ + 2y’’ – 4y’ – 7y = sin x is an equation with constant coefficients.
2) 2y’’ + xy’ – e
x
y = 0 is an equation with variable coefficients.
Theorem: Let
a
0
(x)y
n ( )
+a
1
(x)y
n!1 ( )
+.....+a
n!1
(x) " y +a
n
(x)y =b(x)
with a
0
(x), a
1
(x), …. , a
n
(x) and b(x) are continuous real-valued functions on the interval
[a, b] and a
0
(x) ? 0 for at least one x in [a, b].
Let x
0
be a point on the interval [a, b] and let c
0
, c
1
, c
n-1
be n arbitrary constants.
Conclusion:
There exists a unique function f(x) defined on [a, b] such that f(x) is a solution of the
linear differential equation and satisfies
f(x
0
) = c
0
, f’(x
0
) = c
1
, f’’(x
0
) = c
2
, … , f
(n-1)
(x
0
) = c
n-1
.
Remark: The theorem extends the I.V.P. discussed for first order differential equations
to linear differential equations of order n.
Example:
Consider the I.V.P.
d
2
y
dx
2
+3x
dy
dx
+x
3
y=e
x
y(1)=2
y'(1)= !5
"
#
$
$
%
$
$
a
0
(x) = 1, a
1
(x) = 3x, a
3
(x) = x
3
, and b(x) = e
x
, they are continuous functions everywhere.
We have a linear differential equation order 2. The real numbers c
0
= 2 and c
1
= -5.
Then, according to the theorem there exists an unique function f(x) continuous
everywhere that is the solution of the equation and f(1) = 2 and f(x) = -5.
Corollary: Given the H.L.D.E.
a
0
(x)y
n ( )
+a
1
(x)y
n!1 ( )
+.....+a
n!1
(x) " y +a
n
(x)y =0
with a
0
(x), a
1
(x), …. , a
n
(x) are continuous real-valued functions on the interval [a, b] and
a
0
(x) ? 0 for at least one x in [a, b].
Let f(x) be a solution of the H.L.D.E. such that f(x
0
) = 0, f’(x
0
) = 0, f’’(x
0
) = 0, … ,
f
(n-1)
(x
0
) = 0 where x
0
is in [a, b],
Conclusion:
f(x) = 0 for all x in [a, b].
Example:
y’’’ + 2y’’ + 4xy’ + x
2
y = 0
y(2) = y’(2) = y’’(2) = 0
The unique solution that satisfies the I.V.P. is f(x) = 0
Definition: Given k functions defined on an interval [a, b], f
1
(x), f
2
(x), … , f
k
(x), and k
constants, c
1
, c
2
, … , c
k
. The expression
c
1
f
1
(x) + c
2
f
2
(x) + … + c
k
f
k
(x)
is called a linear combination of f
1
(x), f
2
(x), … , f
k
(x).
Basic Theorem on Homogeneous Linear Differential Equations
Given the n-th order H.L.D.E.
a
0
(x)y
n ( )
+a
1
(x)y
n!1 ( )
+.....+a
n!1
(x) " y +a
n
(x)y =0
let f
1
(x), f
2
(x), … , f
k
(x) be k solutions of the H.L.D.E. on the interval [a, b].
Conclusion:
The linear combination c
1
f
1
(x) + c
2
f
2
(x) + … + c
k
f
k
(x) is a solution of H.L.D.E. on
[a, b] where c
1
, c
2
, … , c
k
are k arbitrary constants.
Example:
Given the H.L.D.E.
d
2
y
dx
2
+y=0 ,
The functions f
1
(x) = sin x and f
2
(x) = cos x are solutions of the equation, since taking
the second derivative of the function f
1
''
(x)=!sin!x and substituting into the equation,
we get: –sin x + sin x = 0. Similarly for the other function.
Then g(x) = c
1
sin x + c
2
cos x is a solution of the equation where c
1
and c
2
are any
arbitrary constant: g’’(x) = - c
1
sinx – c
2
cos x, substituting into the equation we get
- c
1
sinx – c
2
cos x + c
1
sinx + c
2
cos x = 0.
Definition: n functions defined on an interval [a, b], f
1
(x), f
2
(x), … , f
n
(x) are called
linearly dependent on [a, b] if there exist constants c
1
, c
2
, … , c
n
, not all of them zero,
such that the linear combination
c
1
f
1
(x) + c
2
f
2
(x) + … + c
n
f
n
(x) = 0
for all x in [a, b].
Example:
1) The functions f
1
(x) = x
2
and f
2
(x) = 4x
2
are linearly dependent on [-1, 1] since
there exist constants c
1
= - 4 and c
2
= 1 such that c
1
f
1
(x) + c
2
f
2
(x) = -4x
2
+ 4x
2
= 0 for all
x in [-1, 1].
2) The functions f
1
(x) = e
x
, f
2
(x) = - e
x
and f
3
(x) = 8e
x
are linearly dependent on [-10, 10]
since there exist constants c
1
= 5, c
2
= 1 and c
3
= 1 such that
c
1
f
1
(x) + c
2
f
2
(x) + c
3
f
3
(x) = 5e
x
– e
x
+ 4e
x
= 0 for all x in [-10, 10].
Definition: n functions defined on an interval [a, b], f
1
(x), f
2
(x), … , f
n
(x) are called
linearly independent on [a, b] if they are NOT linear dependent on [a, b].
This means that f
1
(x), f
2
(x), … , f
n
(x) are linearly independent on [a, b] if the relation
c
1
f
1
(x) + c
2
f
2
(x) + … + c
n
f
n
(x) = 0 for all x in [a, b]
implies that c
1
= c
2
= … = c
n
= 0.
Example:
The functions f
1
(x) = x
2
, f
2
(x) = x
3
and f
3
(x) = x
5
are linearly independent on [-5, 5] since
the relation
c
1
f
1
(x) + c
2
f
2
(x) + c
3
f
3
(x) = c
1
x
2
+ c
2
x
3
+ c
3
x
5
= 0 for all x in [-5, 5]
if and only if c
1
= c
2
= c
3
= 0.
Theorem: The n-th order H.L.D.E.
a
0
(x)y
n ( )
+a
1
(x)y
n!1 ( )
+.....+a
n!1
(x) " y +a
n
(x)y =0
always possesses n solutions f
1
(x), f
2
(x), … , f
n
(x) that are linearly independent.
Furthermore, if f
1
(x), f
2
(x), … , f
n
(x) are n linearly independent solutions of the equation,
then every solution f(x) of the equation can be expressed as a linear combination
f(x) = c
1
f
1
(x) + c
2
f
2
(x) + … + c
n
f
n
(x)
of those n solutions by a proper choice of constants c
1
, c
2
, … , c
n
.
Example:
Given the 2
nd
order H.L.D.E. y’’ + y = 0,
the functions f
1
(x) = sin x and f
2
(x) = cos x are two linearly independent solutions of the
equation on (-8, 8).
If f(x) is any other solution of the equation then f(x) = c
1
sin x + c
2
cos x, for particular
values of the constants c
1
and c
2
.
For example f(x) = cos(x – p/3) is a solution of the equation,
Since cos(x – p/3) = cos x cos(p/3) + sin x sin(p/3) = ½ cos x +
3
2
sin x, then
f(x) =
3
2
sin x + ½ cos x =
3
2
f
1
(x) + ½ f
2
(x)
Definition: If f
1
(x), f
2
(x), … , f
n
(x) are n linearly independent solutions of the H.L.D.E.
a
0
(x)y
n ( )
+a
1
(x)y
n!1 ( )
+.....+a
n!1
(x) " y +a
n
(x)y =0
on [a, b], then the set { f
1
(x), f
2
(x), … , f
n
(x)} is called the fundamental set of solutions
of the equation.
The function f(x) = c
1
f
1
(x) + c
2
f
2
(x) + … + c
n
f
n
(x) where c
1
, c
2
, … , c
n
are arbitrary
constants is called a general solution of the equation.
Example:
Given the 3
rd
order H.L.D.E. y’’’ - 2y’’ – y’ + 2y = 0,
the functions f
1
(x) = e
x
, f
2
(x) = e
-x
, and f
3
(x) = e
2x
are three linearly independent solutions
of the equation on (-8, 8).
The set {e
x
, e
-x
, e
2x
} is the fundamental set of solutions.
Then f(x) = c
1
ex+ c
2
e-x + c
3
e
2x
, where c
1
, c
2
and c
3
are arbitrary constants is a general
solution of the equation.
Definition: Let f
1
(x), f
2
(x), … , f
n
(x) be n real-valued functions defined on [a, b] such that
the (n -1)-st derivative of each function exists in [a, b].
The determinant
W f
1
,f
2
,...,f
n
( )(x)=
f
1
(x) f
2
(x) ! f
n
(x)
f
1
'
(x) f
2
'
(x) ! f
n
'
(x)
! ! ! !
f
1
(n!1)
(x) f
2
(n!1)
(x) ! f
n
(n!1)
(x)
is called the Wronskian of f
1
(x), f
2
(x), … , f
n
(x).
Remark: The Wronskian is also a function of x.
Theorem: The n solutions f
1
(x), f
2
(x), … , f
n
(x) of the n-th H.L.D.E.
a
0
(x)y
n ( )
+a
1
(x)y
n!1 ( )
+.....+a
n!1
(x) " y +a
n
(x)y =0
are linearly independent on [a, b] if and only if W(f
1
, f
2
, … , f
n
) (x) ? 0 for at least one x
on [a, b].
Example:
Page 5
Basic Theory of Linear O.D.E.’s
Definition: A linear O.D.E. of order n, in the independent variable x and the dependent
variable y is an equation that can be expressed in the form:
a
0
(x)y
n ( )
+a
1
(x)y
n!1 ( )
+.....+a
n!1
(x) " y +a
n
(x)y =b(x)
We will assume that a
0
(x), a
1
(x), …. , a
n
(x) and b(x) are continuous real-valued functions
on the interval [a, b] and a
0
(x) ? 0 for at least one x in [a, b].
Remark: A linear ODE satisfies the following conditions:
1- The dependent variable y and its derivatives occur to the first degree only.
2- No products of y and/or any of its derivatives appear in the equation.
3- No transcendental functions of y and/or its derivatives occur.
Definition: Equations that not satisfy the above conditions are called nonlinear.
Remark:
1) The functions a
0
(x), a
1
(x), …. , a
n
(x) are called the coefficients of the equation.
2) The right-hand member b(x) is called the non-homogeneous term.
3) If b(x) = 0, then the equation reduces to
a
0
(x)y
n ( )
+a
1
(x)y
n!1 ( )
+.....+a
n!1
(x) " y +a
n
(x)y =0
and it is called a homogeneous linear differential equation (H.L.D.E.).
Example:
1)
d
3
y
dx
3
!cos(x)
d
2
y
dx
2
+3x
dy
dx
+x
3
y=e
x
is a linear differential equation of order 3,
where a
0
(x) = 1, a
2
(x) = - cos(x), a
3
(x) = 3x, a
4
(x) = x
3
and b(x) = e
x
, they are all
continuous function on
! .
Definition: If a
0
, a
1
, …. , a
n
are all constants, then we have a linear differential equation
with constant coefficients, otherwise we have an equation with variable coefficients.
Example:
1) 3y’’’ + 2y’’ – 4y’ – 7y = sin x is an equation with constant coefficients.
2) 2y’’ + xy’ – e
x
y = 0 is an equation with variable coefficients.
Theorem: Let
a
0
(x)y
n ( )
+a
1
(x)y
n!1 ( )
+.....+a
n!1
(x) " y +a
n
(x)y =b(x)
with a
0
(x), a
1
(x), …. , a
n
(x) and b(x) are continuous real-valued functions on the interval
[a, b] and a
0
(x) ? 0 for at least one x in [a, b].
Let x
0
be a point on the interval [a, b] and let c
0
, c
1
, c
n-1
be n arbitrary constants.
Conclusion:
There exists a unique function f(x) defined on [a, b] such that f(x) is a solution of the
linear differential equation and satisfies
f(x
0
) = c
0
, f’(x
0
) = c
1
, f’’(x
0
) = c
2
, … , f
(n-1)
(x
0
) = c
n-1
.
Remark: The theorem extends the I.V.P. discussed for first order differential equations
to linear differential equations of order n.
Example:
Consider the I.V.P.
d
2
y
dx
2
+3x
dy
dx
+x
3
y=e
x
y(1)=2
y'(1)= !5
"
#
$
$
%
$
$
a
0
(x) = 1, a
1
(x) = 3x, a
3
(x) = x
3
, and b(x) = e
x
, they are continuous functions everywhere.
We have a linear differential equation order 2. The real numbers c
0
= 2 and c
1
= -5.
Then, according to the theorem there exists an unique function f(x) continuous
everywhere that is the solution of the equation and f(1) = 2 and f(x) = -5.
Corollary: Given the H.L.D.E.
a
0
(x)y
n ( )
+a
1
(x)y
n!1 ( )
+.....+a
n!1
(x) " y +a
n
(x)y =0
with a
0
(x), a
1
(x), …. , a
n
(x) are continuous real-valued functions on the interval [a, b] and
a
0
(x) ? 0 for at least one x in [a, b].
Let f(x) be a solution of the H.L.D.E. such that f(x
0
) = 0, f’(x
0
) = 0, f’’(x
0
) = 0, … ,
f
(n-1)
(x
0
) = 0 where x
0
is in [a, b],
Conclusion:
f(x) = 0 for all x in [a, b].
Example:
y’’’ + 2y’’ + 4xy’ + x
2
y = 0
y(2) = y’(2) = y’’(2) = 0
The unique solution that satisfies the I.V.P. is f(x) = 0
Definition: Given k functions defined on an interval [a, b], f
1
(x), f
2
(x), … , f
k
(x), and k
constants, c
1
, c
2
, … , c
k
. The expression
c
1
f
1
(x) + c
2
f
2
(x) + … + c
k
f
k
(x)
is called a linear combination of f
1
(x), f
2
(x), … , f
k
(x).
Basic Theorem on Homogeneous Linear Differential Equations
Given the n-th order H.L.D.E.
a
0
(x)y
n ( )
+a
1
(x)y
n!1 ( )
+.....+a
n!1
(x) " y +a
n
(x)y =0
let f
1
(x), f
2
(x), … , f
k
(x) be k solutions of the H.L.D.E. on the interval [a, b].
Conclusion:
The linear combination c
1
f
1
(x) + c
2
f
2
(x) + … + c
k
f
k
(x) is a solution of H.L.D.E. on
[a, b] where c
1
, c
2
, … , c
k
are k arbitrary constants.
Example:
Given the H.L.D.E.
d
2
y
dx
2
+y=0 ,
The functions f
1
(x) = sin x and f
2
(x) = cos x are solutions of the equation, since taking
the second derivative of the function f
1
''
(x)=!sin!x and substituting into the equation,
we get: –sin x + sin x = 0. Similarly for the other function.
Then g(x) = c
1
sin x + c
2
cos x is a solution of the equation where c
1
and c
2
are any
arbitrary constant: g’’(x) = - c
1
sinx – c
2
cos x, substituting into the equation we get
- c
1
sinx – c
2
cos x + c
1
sinx + c
2
cos x = 0.
Definition: n functions defined on an interval [a, b], f
1
(x), f
2
(x), … , f
n
(x) are called
linearly dependent on [a, b] if there exist constants c
1
, c
2
, … , c
n
, not all of them zero,
such that the linear combination
c
1
f
1
(x) + c
2
f
2
(x) + … + c
n
f
n
(x) = 0
for all x in [a, b].
Example:
1) The functions f
1
(x) = x
2
and f
2
(x) = 4x
2
are linearly dependent on [-1, 1] since
there exist constants c
1
= - 4 and c
2
= 1 such that c
1
f
1
(x) + c
2
f
2
(x) = -4x
2
+ 4x
2
= 0 for all
x in [-1, 1].
2) The functions f
1
(x) = e
x
, f
2
(x) = - e
x
and f
3
(x) = 8e
x
are linearly dependent on [-10, 10]
since there exist constants c
1
= 5, c
2
= 1 and c
3
= 1 such that
c
1
f
1
(x) + c
2
f
2
(x) + c
3
f
3
(x) = 5e
x
– e
x
+ 4e
x
= 0 for all x in [-10, 10].
Definition: n functions defined on an interval [a, b], f
1
(x), f
2
(x), … , f
n
(x) are called
linearly independent on [a, b] if they are NOT linear dependent on [a, b].
This means that f
1
(x), f
2
(x), … , f
n
(x) are linearly independent on [a, b] if the relation
c
1
f
1
(x) + c
2
f
2
(x) + … + c
n
f
n
(x) = 0 for all x in [a, b]
implies that c
1
= c
2
= … = c
n
= 0.
Example:
The functions f
1
(x) = x
2
, f
2
(x) = x
3
and f
3
(x) = x
5
are linearly independent on [-5, 5] since
the relation
c
1
f
1
(x) + c
2
f
2
(x) + c
3
f
3
(x) = c
1
x
2
+ c
2
x
3
+ c
3
x
5
= 0 for all x in [-5, 5]
if and only if c
1
= c
2
= c
3
= 0.
Theorem: The n-th order H.L.D.E.
a
0
(x)y
n ( )
+a
1
(x)y
n!1 ( )
+.....+a
n!1
(x) " y +a
n
(x)y =0
always possesses n solutions f
1
(x), f
2
(x), … , f
n
(x) that are linearly independent.
Furthermore, if f
1
(x), f
2
(x), … , f
n
(x) are n linearly independent solutions of the equation,
then every solution f(x) of the equation can be expressed as a linear combination
f(x) = c
1
f
1
(x) + c
2
f
2
(x) + … + c
n
f
n
(x)
of those n solutions by a proper choice of constants c
1
, c
2
, … , c
n
.
Example:
Given the 2
nd
order H.L.D.E. y’’ + y = 0,
the functions f
1
(x) = sin x and f
2
(x) = cos x are two linearly independent solutions of the
equation on (-8, 8).
If f(x) is any other solution of the equation then f(x) = c
1
sin x + c
2
cos x, for particular
values of the constants c
1
and c
2
.
For example f(x) = cos(x – p/3) is a solution of the equation,
Since cos(x – p/3) = cos x cos(p/3) + sin x sin(p/3) = ½ cos x +
3
2
sin x, then
f(x) =
3
2
sin x + ½ cos x =
3
2
f
1
(x) + ½ f
2
(x)
Definition: If f
1
(x), f
2
(x), … , f
n
(x) are n linearly independent solutions of the H.L.D.E.
a
0
(x)y
n ( )
+a
1
(x)y
n!1 ( )
+.....+a
n!1
(x) " y +a
n
(x)y =0
on [a, b], then the set { f
1
(x), f
2
(x), … , f
n
(x)} is called the fundamental set of solutions
of the equation.
The function f(x) = c
1
f
1
(x) + c
2
f
2
(x) + … + c
n
f
n
(x) where c
1
, c
2
, … , c
n
are arbitrary
constants is called a general solution of the equation.
Example:
Given the 3
rd
order H.L.D.E. y’’’ - 2y’’ – y’ + 2y = 0,
the functions f
1
(x) = e
x
, f
2
(x) = e
-x
, and f
3
(x) = e
2x
are three linearly independent solutions
of the equation on (-8, 8).
The set {e
x
, e
-x
, e
2x
} is the fundamental set of solutions.
Then f(x) = c
1
ex+ c
2
e-x + c
3
e
2x
, where c
1
, c
2
and c
3
are arbitrary constants is a general
solution of the equation.
Definition: Let f
1
(x), f
2
(x), … , f
n
(x) be n real-valued functions defined on [a, b] such that
the (n -1)-st derivative of each function exists in [a, b].
The determinant
W f
1
,f
2
,...,f
n
( )(x)=
f
1
(x) f
2
(x) ! f
n
(x)
f
1
'
(x) f
2
'
(x) ! f
n
'
(x)
! ! ! !
f
1
(n!1)
(x) f
2
(n!1)
(x) ! f
n
(n!1)
(x)
is called the Wronskian of f
1
(x), f
2
(x), … , f
n
(x).
Remark: The Wronskian is also a function of x.
Theorem: The n solutions f
1
(x), f
2
(x), … , f
n
(x) of the n-th H.L.D.E.
a
0
(x)y
n ( )
+a
1
(x)y
n!1 ( )
+.....+a
n!1
(x) " y +a
n
(x)y =0
are linearly independent on [a, b] if and only if W(f
1
, f
2
, … , f
n
) (x) ? 0 for at least one x
on [a, b].
Example:
1) Show that the functions f
1
(x) = e
x
, f
2
(x) = e
-x
, and f
3
(x) = e
2x
are three linearly
independent solutions of the 3
rd
order H.L.D.E. y’’’ - 2y’’ – y’ + 2y = 0, on (-8, 8).
Let’s compute the Wronskian
W e
x
,e
!x
,e
2x
( )
=
e
x
e
!x
e
2x
e
x
!e
!x
2e
2x
e
x
e
!x
4e
2x
=e
x
e
!x
e
2x
1 1 1
1 !1 2
1 1 4
=e
2x
(!6)"0 for all x.
2) Show that the functions f
1
(x) = x
2
, f
2
(x) = x
3
, and f
3
(x) = x
-2
are three linearly
independent solutions of the 3
rd
order H.L.D.E. x
3
y’’’ – 6xy’ + 12y = 0, on (-8, 8).
Let’s compute the Wronskian
W(x
2
,x
3
,x
!2
)=
x
2
x
3
x
!2
2x 3x
2
!2x
!3
2 6x 6x
!4
=x
2
3x
2
!2x
!3
6x 6x
!4
!x
3
2x !2x
!3
2 6x
!4
+x
!2
2x 3x
2
2 6x
=x
2
18x
!2
+12x
!2
( )
!x
3
12x
!3
+4x
!3
( )
+x
!2
12x
2
!6x
2
( )
=30!16+6 =20"0
The Non-Homogeneous Linear Differential Equation
Given the n-th order non-homogeneous linear differential equation
a
0
(x)y
n ( )
+a
1
(x)y
n!1 ( )
+.....+a
n!1
(x) " y +a
n
(x)y =b(x)
then the n-th order H.L.D.E.
a
0
(x)y
n ( )
+a
1
(x)y
n!1 ( )
+.....+a
n!1
(x) " y +a
n
(x)y =0
is called the corresponding homogeneous equation.
Remark: Every non-homogeneous differential equation has a corresponding
homogeneous equation; we obtain it from the non-homogeneous replacing the non-
homogeneous term by zero.
Theorem: Let v(x) be a solution of the non-homogeneous equation
a
0
(x)y
n ( )
+a
1
(x)y
n!1 ( )
+.....+a
n!1
(x) " y +a
n
(x)y =b(x)
Let u(x) be a solution of the corresponding homogeneous equation
a
0
(x)y
n ( )
+a
1
(x)y
n!1 ( )
+.....+a
n!1
(x) " y +a
n
(x)y =0 .
Conclusion:
Then u(x) + v(x) is also a solution of the non-homogeneous equation.
Example:
Given the non-homogeneous equation y’’ + y = x,
The function v(x) = x is a solution of the equation.
The corresponding homogeneous equation is y’’ + y = 0, and u(x) = sin x is a solution of
this equation.
Then v(x) + u(x) = x + sin x is also a solution of the non-homogeneous equation.
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FAQs on General Theory of Homogeneous and Non-Homogeneous linear ODEs - CSIR-NET Mathematical Sciences - Mathematics for IIT JAM, GATE, CSIR NET, UGC NET
| 1. What is a homogeneous linear ordinary differential equation (ODE)? |  |
Ans. A homogeneous linear ODE is a differential equation in which all the terms involving the dependent variable and its derivatives are of degree 1 and are multiplied by the same function. In other words, a homogeneous linear ODE can be written in the form:
\[a_n(x)y^{(n)}(x) + a_{n-1}(x)y^{(n-1)}(x) + \ldots + a_1(x)y'(x) + a_0(x)y(x) = 0\]
where \(y(x)\) is the unknown function, \(y^{(n)}(x)\) denotes the \(n\)th derivative of \(y(x)\) with respect to \(x\), and \(a_n(x), a_{n-1}(x), \ldots, a_1(x), a_0(x)\) are functions of \(x\) only.
| 2. What is a non-homogeneous linear ordinary differential equation (ODE)? | |
Ans. A non-homogeneous linear ODE is a differential equation in which the dependent variable and its derivatives are multiplied by functions of different degrees. In other words, a non-homogeneous linear ODE can be written in the form:
\[a_n(x)y^{(n)}(x) + a_{n-1}(x)y^{(n-1)}(x) + \ldots + a_1(x)y'(x) + a_0(x)y(x) = g(x)\]
where \(g(x)\) is a non-zero function of \(x\) and represents the inhomogeneous term.
| 3. What is the general theory for solving homogeneous linear ODEs? | |
Ans. The general theory for solving homogeneous linear ODEs states that if \(y_1(x), y_2(x), \ldots, y_n(x)\) are \(n\) linearly independent solutions of the homogeneous linear ODE, then the general solution can be written as a linear combination of these solutions. That is, the general solution is of the form:
\[y(x) = c_1y_1(x) + c_2y_2(x) + \ldots + c_ny_n(x)\]
where \(c_1, c_2, \ldots, c_n\) are arbitrary constants.
| 4. What is the general theory for solving non-homogeneous linear ODEs? | |
Ans. The general theory for solving non-homogeneous linear ODEs states that if \(y_p(x)\) is a particular solution of the non-homogeneous linear ODE and \(y_1(x), y_2(x), \ldots, y_n(x)\) are \(n\) linearly independent solutions of the corresponding homogeneous linear ODE, then the general solution can be written as the sum of the particular solution and the general solution of the homogeneous ODE. That is, the general solution is given by:
\[y(x) = y_p(x) + c_1y_1(x) + c_2y_2(x) + \ldots + c_ny_n(x)\]
where \(c_1, c_2, \ldots, c_n\) are arbitrary constants.
| 5. How can we determine the particular solution of a non-homogeneous linear ODE? | |
Ans. To determine the particular solution of a non-homogeneous linear ODE, various methods can be used, such as the method of undetermined coefficients, variation of parameters, or using Green's function. The choice of method depends on the specific form of the inhomogeneous term and the coefficients in the ODE. Each method involves finding the particular solution that satisfies the given ODE and substituting it back into the original equation to ensure it is a valid solution.
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