JEE Exam  >  JEE Notes  >  Mathematics (Maths) for JEE Main & Advanced  >  Important Formulas: Differential Equations

Important Differential Equations Formulas for JEE and NEET

Download, print and study this document offline
Please wait while the PDF view is loading
 Page 1


DIFFERENTIAL EQUATIONS 
A differential equation is a mathematical equation that relates 
some function with its derivatives 
Order and Degree of a Differential Equation: 
The order of the highest differential coefficient appearing in the 
differential equation is called the order of the differential 
equation, while the exponent of the highest differential 
coefficient, when the differential equation is a polynomial in all 
the differential coefficients, is known as the degree of the 
differential equation.  
Formation of Differential Equations:  
Consider a family of curves f( x, y, ?
1
, ?
2
,…, ?
n
) = 0, where ?
1
, 
?
2
,…, ?
n
 are n independent  parameters.
Solution of Differential Equation 
First Order Differential Equations with Separable Variables 
 Let  
? ?
? ?
?
Mx
dy
dx Ny
? N(y) dy = M(x) dx 
Integrating both sides of (2), we get the solution viz.
? ? ? ? ??
??
N y dy M x dx c
Differential Equations Reducible to the Separable Variable 
Type: 
A differential equation of the form ?
dy
dx
f (ax + by + c) is solved by 
writing ax + by + c = t. 
Page 2


DIFFERENTIAL EQUATIONS 
A differential equation is a mathematical equation that relates 
some function with its derivatives 
Order and Degree of a Differential Equation: 
The order of the highest differential coefficient appearing in the 
differential equation is called the order of the differential 
equation, while the exponent of the highest differential 
coefficient, when the differential equation is a polynomial in all 
the differential coefficients, is known as the degree of the 
differential equation.  
Formation of Differential Equations:  
Consider a family of curves f( x, y, ?
1
, ?
2
,…, ?
n
) = 0, where ?
1
, 
?
2
,…, ?
n
 are n independent  parameters.
Solution of Differential Equation 
First Order Differential Equations with Separable Variables 
 Let  
? ?
? ?
?
Mx
dy
dx Ny
? N(y) dy = M(x) dx 
Integrating both sides of (2), we get the solution viz.
? ? ? ? ??
??
N y dy M x dx c
Differential Equations Reducible to the Separable Variable 
Type: 
A differential equation of the form ?
dy
dx
f (ax + by + c) is solved by 
writing ax + by + c = t. 
 
 
 
Homogeneous Differential Equations:  
Suppose we have a differential equation of the form ? ? ?
dy
f x,y ,
dx
  
where f(x,y) is a function of x and y and  is of the form 
?? ??
?? ??
?? ??
y x
F or F .
xy
 
These equations are solved by putting y = vx, where v ?v (x),  a 
function of x. 
 
Equations Reducible to the Homogenous Form:  
Equations of the form 
??
?
??
dy ax by c
dx Ax By C
 
(aB ? Ab) can be reduced to a homogenous form by changing the 
variables  x, y to X, Y by writing  x = X + h and  y = Y + k; 
where h, k are constants to be chosen so as to make the given 
equation homogenous. We have 
? ?
? ?
?
??
?
d Y k
dy dY
dx dX d X h
. Hence  the  given  equation  becomes
? ?
? ?
?
? ? ? ?
aX + bY + ah + bk + c
dY
dX AX BY Ah Bk C
 
Let h and k be so chosen as to satisfy the relation ah + bk + c = 0 
and Ah + Bk + C =0. 
These give 
??
??
??
bC Bc Ac aC
hk
aB Ab aB Ab
 
which are meaningful except when aB = Ab. 
?
?
?
dY aX bY
dX AX BY
can now be solved by means of the substitution Y = VX 
In case aB = Ab, we write ax + by = t.  
 
First Order Linear Differential Equations:  
The most general form of this category of differential equations 
is ??
dy
Py Q,
dx
, where P and Q are functions of x alone.  
Page 3


DIFFERENTIAL EQUATIONS 
A differential equation is a mathematical equation that relates 
some function with its derivatives 
Order and Degree of a Differential Equation: 
The order of the highest differential coefficient appearing in the 
differential equation is called the order of the differential 
equation, while the exponent of the highest differential 
coefficient, when the differential equation is a polynomial in all 
the differential coefficients, is known as the degree of the 
differential equation.  
Formation of Differential Equations:  
Consider a family of curves f( x, y, ?
1
, ?
2
,…, ?
n
) = 0, where ?
1
, 
?
2
,…, ?
n
 are n independent  parameters.
Solution of Differential Equation 
First Order Differential Equations with Separable Variables 
 Let  
? ?
? ?
?
Mx
dy
dx Ny
? N(y) dy = M(x) dx 
Integrating both sides of (2), we get the solution viz.
? ? ? ? ??
??
N y dy M x dx c
Differential Equations Reducible to the Separable Variable 
Type: 
A differential equation of the form ?
dy
dx
f (ax + by + c) is solved by 
writing ax + by + c = t. 
 
 
 
Homogeneous Differential Equations:  
Suppose we have a differential equation of the form ? ? ?
dy
f x,y ,
dx
  
where f(x,y) is a function of x and y and  is of the form 
?? ??
?? ??
?? ??
y x
F or F .
xy
 
These equations are solved by putting y = vx, where v ?v (x),  a 
function of x. 
 
Equations Reducible to the Homogenous Form:  
Equations of the form 
??
?
??
dy ax by c
dx Ax By C
 
(aB ? Ab) can be reduced to a homogenous form by changing the 
variables  x, y to X, Y by writing  x = X + h and  y = Y + k; 
where h, k are constants to be chosen so as to make the given 
equation homogenous. We have 
? ?
? ?
?
??
?
d Y k
dy dY
dx dX d X h
. Hence  the  given  equation  becomes
? ?
? ?
?
? ? ? ?
aX + bY + ah + bk + c
dY
dX AX BY Ah Bk C
 
Let h and k be so chosen as to satisfy the relation ah + bk + c = 0 
and Ah + Bk + C =0. 
These give 
??
??
??
bC Bc Ac aC
hk
aB Ab aB Ab
 
which are meaningful except when aB = Ab. 
?
?
?
dY aX bY
dX AX BY
can now be solved by means of the substitution Y = VX 
In case aB = Ab, we write ax + by = t.  
 
First Order Linear Differential Equations:  
The most general form of this category of differential equations 
is ??
dy
Py Q,
dx
, where P and Q are functions of x alone.  
 
 
 
We use here an Integrating factor, namely 
?
pdx
e and the solution is 
obtained by  
??
??
?
pdx pdx
y e Q e dx c , where c is an arbitrary constant. 
 
General Form of Variable Separation 
(i)  d(x + y) =  dx +  dy (ii)  d(xy) = y dx + x dy 
(iii)  d
??
??
??
x
y
 =
2
y dx-x dy
y
 (iv)  d
??
??
??
y
x
 = 
2
x dy-y dx
x
 
(v)  d(log xy) =
ydx+xdy
xy
 (vi)  d
? ? ?
??
?
??
??
xdy ydx
y
log
x xy
 
(vii)  
??
?
??
? ??
22
x+y x dy-y dx 1
d log 
2 x-y
xy
 (viii)  
?
??
?
??
? ??
1
22
y x dy-y dx
d tan
x
xy
 
(ix)  
? ?
?
??
??
?
1n
d f x,y
1n
=
? ?
? ? ? ?
?
n
f x,y
f x,y
 (x)  d
? ?
22
22
xdx ydx
xy
xy
?
??
?
 
 
ORTHOGONAL TRAJECTORY 
Any curve, which cuts every member of a given family of curves 
at right angle, is called an orthogonal trajectory of the family. For 
example, each straight line passing through the origin, i.e. y = kx 
is an orthogonal trajectory of the family of the circles x
2
 + y
2
 = a
2
 
 
 
APPLICATION OF DIFFERENTIAL EQUATIONS 
Geometrical Applications  
We also use differential equations for finding the family of curves 
for which some conditions involving the derivatives are given. 
For this we proceed in the following way: 
Equation of the tangent at a point (x, y) to the curve y = f(x) is 
given by  
Page 4


DIFFERENTIAL EQUATIONS 
A differential equation is a mathematical equation that relates 
some function with its derivatives 
Order and Degree of a Differential Equation: 
The order of the highest differential coefficient appearing in the 
differential equation is called the order of the differential 
equation, while the exponent of the highest differential 
coefficient, when the differential equation is a polynomial in all 
the differential coefficients, is known as the degree of the 
differential equation.  
Formation of Differential Equations:  
Consider a family of curves f( x, y, ?
1
, ?
2
,…, ?
n
) = 0, where ?
1
, 
?
2
,…, ?
n
 are n independent  parameters.
Solution of Differential Equation 
First Order Differential Equations with Separable Variables 
 Let  
? ?
? ?
?
Mx
dy
dx Ny
? N(y) dy = M(x) dx 
Integrating both sides of (2), we get the solution viz.
? ? ? ? ??
??
N y dy M x dx c
Differential Equations Reducible to the Separable Variable 
Type: 
A differential equation of the form ?
dy
dx
f (ax + by + c) is solved by 
writing ax + by + c = t. 
 
 
 
Homogeneous Differential Equations:  
Suppose we have a differential equation of the form ? ? ?
dy
f x,y ,
dx
  
where f(x,y) is a function of x and y and  is of the form 
?? ??
?? ??
?? ??
y x
F or F .
xy
 
These equations are solved by putting y = vx, where v ?v (x),  a 
function of x. 
 
Equations Reducible to the Homogenous Form:  
Equations of the form 
??
?
??
dy ax by c
dx Ax By C
 
(aB ? Ab) can be reduced to a homogenous form by changing the 
variables  x, y to X, Y by writing  x = X + h and  y = Y + k; 
where h, k are constants to be chosen so as to make the given 
equation homogenous. We have 
? ?
? ?
?
??
?
d Y k
dy dY
dx dX d X h
. Hence  the  given  equation  becomes
? ?
? ?
?
? ? ? ?
aX + bY + ah + bk + c
dY
dX AX BY Ah Bk C
 
Let h and k be so chosen as to satisfy the relation ah + bk + c = 0 
and Ah + Bk + C =0. 
These give 
??
??
??
bC Bc Ac aC
hk
aB Ab aB Ab
 
which are meaningful except when aB = Ab. 
?
?
?
dY aX bY
dX AX BY
can now be solved by means of the substitution Y = VX 
In case aB = Ab, we write ax + by = t.  
 
First Order Linear Differential Equations:  
The most general form of this category of differential equations 
is ??
dy
Py Q,
dx
, where P and Q are functions of x alone.  
 
 
 
We use here an Integrating factor, namely 
?
pdx
e and the solution is 
obtained by  
??
??
?
pdx pdx
y e Q e dx c , where c is an arbitrary constant. 
 
General Form of Variable Separation 
(i)  d(x + y) =  dx +  dy (ii)  d(xy) = y dx + x dy 
(iii)  d
??
??
??
x
y
 =
2
y dx-x dy
y
 (iv)  d
??
??
??
y
x
 = 
2
x dy-y dx
x
 
(v)  d(log xy) =
ydx+xdy
xy
 (vi)  d
? ? ?
??
?
??
??
xdy ydx
y
log
x xy
 
(vii)  
??
?
??
? ??
22
x+y x dy-y dx 1
d log 
2 x-y
xy
 (viii)  
?
??
?
??
? ??
1
22
y x dy-y dx
d tan
x
xy
 
(ix)  
? ?
?
??
??
?
1n
d f x,y
1n
=
? ?
? ? ? ?
?
n
f x,y
f x,y
 (x)  d
? ?
22
22
xdx ydx
xy
xy
?
??
?
 
 
ORTHOGONAL TRAJECTORY 
Any curve, which cuts every member of a given family of curves 
at right angle, is called an orthogonal trajectory of the family. For 
example, each straight line passing through the origin, i.e. y = kx 
is an orthogonal trajectory of the family of the circles x
2
 + y
2
 = a
2
 
 
 
APPLICATION OF DIFFERENTIAL EQUATIONS 
Geometrical Applications  
We also use differential equations for finding the family of curves 
for which some conditions involving the derivatives are given. 
For this we proceed in the following way: 
Equation of the tangent at a point (x, y) to the curve y = f(x) is 
given by  
 
 
 
Y ?y = ? ? ?
dy
Xx
dx
, At the X axis, Y = 0, and  X = x - y/
dy
dx
.  
At the Y axis, X = 0, and Y = y ? x
dy
dx
. 
Similar information can be obtained for normals by writing its 
equation as (y - y)
dy
dx
 + (X-x) =0. 
 
Read More
209 videos|443 docs|143 tests

Top Courses for JEE

209 videos|443 docs|143 tests
Download as PDF
Explore Courses for JEE exam

Top Courses for JEE

Signup for Free!
Signup to see your scores go up within 7 days! Learn & Practice with 1000+ FREE Notes, Videos & Tests.
10M+ students study on EduRev
Related Searches

practice quizzes

,

ppt

,

Summary

,

study material

,

Objective type Questions

,

video lectures

,

shortcuts and tricks

,

Viva Questions

,

Free

,

Previous Year Questions with Solutions

,

Important Differential Equations Formulas for JEE and NEET

,

Important Differential Equations Formulas for JEE and NEET

,

Semester Notes

,

past year papers

,

pdf

,

mock tests for examination

,

MCQs

,

Sample Paper

,

Extra Questions

,

Important questions

,

Exam

,

Important Differential Equations Formulas for JEE and NEET

;