How to Get Over indefinite Integration ?

How to Get Over indefinite Integration ?

In this article , we will cover the topic Indefinite Integration. This has been written specially taking care of needs & demands of Engineering Aspirants and everything necessary has been added . In the next article i will discuss some interesting problems on Indefinite Integration . In the previous article   i have already discussed Differential Calculus .

Primitive or Anti-derivative.

The integral or primitive or anti-derivative of a function f (x) w.r.t. x is the function whose derivative w.r.t. x is f(x) and we write it as .

The process of finding the function is called “integration”

Indefinite Integral.

Let f(x) be a function. Then the collection of all its primitives is called the indefinite integral of f(x) and is denoted by Thus,

Where is primitive of and C is an arbitrary constant known as the constant of integration.

Here is the integral sign, f(x) is the integrand, x is the variable of integration and dx is the element of integration or differential of x. The process of finding an indefinite integral of a given function is called integration of the function.

It follows from the above discussion that integration of a function f(x) means finding a function such that

Basic theorems on Integration.

If f(x) and g(x) are function of x and a is a constant, then

(1)     (2)

(3) (4)

where C is an arbitrary constant known as the constant of integration.

Fundamental Integration Formulae.

Since therefore based upon this definition and various standard differentiation formulae, we obtain the following integration formulae.

(1)
(2)

(3)
(4)

By applying this procedure we can find out following integration

(5) (6)

(7) (8)

(9) (10)

(11) (12)

(13) (14)

(15) (16)

(17) (18)

(19) (20)

(21) (22)

(23) (24)

Methods of integration.

(1) Integration by substitution             (2) Integration by parts

(3) Integration of rational algebraic functions by using partial fractions.

(1) Integration by substitution : Generally we apply this method in the following cases

(i) When integrand is a function of function : . Here we put . So that and in that case the integral is reduced to

(ii) When integrand is product : of two factors such that one is the derivatives of other

In this case we put =t and convert it to standard integral.

Now ; \

(iii) Integral of a function of the form : We put ax + b = t and convert it into standard integral.

Now .

(iv) Standard form of integrals :

(a)     put (b) , , put

(c)    , put

(v) Standard substitution:

(2) Integration by parts : If u and v are two functions of then i.e., the integral of the product of two function = (first function) × (integral of second function) –integral of {(differentiation of first function) × (integral of second function)}

Note : q Integration with the help of the above rule is called the integration by parts. In the above rule there are two terms on RHS and in both the terms the integral of the second function is involved. Therefore in the product of two function if one of the two functions is not directly integral etc.) we take it as the first function and the remaining function is taken as the second function. If in the integral both the functions are easily integrable then the first function is chosen in such a way that the derivative of the function is a simple function and the function thus obtained under the integrable sign is easily integrable than the original function. Hence, choice of first and second function should be proper.

Note : q We can also choose the first function as the function which comes first in the word ILATE, where

I Stands for the inverse trigonometric function etc.

L Stands for the logarithmic function.

A Stands for the algebraic functions.

T Stands for the trigonometric functions.

E Stands for the exponential functions.

(3) Integration by partial fraction
: If and are two polynomials, then defines a rational algebraic function or a rational function of x.

If degree of degree of then is called a proper rational function.

If degree of degree of , then is called an improper rational function.

If is an improper rational function, we divide by so that the rational function is expressed in the form where and are polynomials such that the degree of is less than that of Thus, is expressible as the sum of a polynomial and a proper rational function.

Any proper rational function can be expressed as the sum of rational functions, each having a simple factor of Each such fraction is called a partial fraction and the process of obtaining them a called the resolution or decomposition of into partial fractions. The resolution of into partial fractions depends mainly upon the nature of the factors of as discussed below.

To Express into partial fraction

Example : . To
find out value of A, we put in left hand side except and obtain value will be value of A in same way, except and except we get the value of B and C respectively.

Evaluations of integration when.

(1) Integrals of the form : To evaluate this type of integrals we express as the sum or difference of two squares by using the following steps.

Step I : Make the coefficient of x² unity by taking it common.

Step II : Add and subtract the square of half of the coefficient of x.

Step III : Apply one of the formulae

(2) Integrals of the form
: To evaluate this type of integrals, we express as the sum or difference of two squares by using the following steps.

Step I : Make the coefficient of unity by taking it common.

Step II : Add and subtract
square of half of the coefficient of x.

Step III : Apply formulae ,

(3) Integrals of the form dx : To evaluated this type of integrals we express the numerator as follows:

(Diff. of denominator) , where and are constants to be determined by equating the coefficients of similar terms on both sides. So we have

(4) Integrals of the form
: To evaluate this type of integrals we express the numerator as follows: (Diff. of denominator) +

Where and are constants to be determined by equating the coefficients of similar terms on both sides. So     we have,

(5)Integrals of the form : :

To evaluate this type of integrals we proceed as follows

Step I : Divide numerator and denominator both by

Step II : Replace

if any in denominator by

Step III : Put

so that

After applying these three steps the integral will reduce to the form
dt which can be evaluated by the method discussed earlier.

(6) Integrals of the form
: To evaluate this type of integrals we proceed as follows

Step I : Put

Step II : Replace in the numerator by sec²
.

Step III : Put so that

After performing these three steps the integral reduces to the form which can be evaluated by the method discussed earlier.

(7) Integrals of the form
: To evaluate this type of integrals we express the numerator as follows: Numerator =(Diff. of denominator) (denominator)

i.e., =

Where and are constants to be determined by comparing the coefficients of and on both sides.

== =

(8) Integrals of the form
: To evaluate integrals of the type we express the linear factor as follows:

Where and are constants to be determined by equating the coefficients of similar terms on both sides. So we have

The first integral on RHS is evaluated by putting and the second integral is evaluated by using .

(9) Integrals of the from , , where is a constant : To evaluate this type of integrals, divide the numerator and denominator by x² and putor whichever on differentiation gives the numerator of the resulting integrand.

(10) Integral of the form
– : Where P and Q linear or quadratic in x, by following substitution, we can change this integral into simple form:

(i) When P and Q both are linear, put Q = t² (ii)
When P is linear and Q is quadratic

(iii) Both P and Q are quadratic put (iv)
When P is quadratic and Q is linear put

(11) Integrals of the form
Where
m, n
are positive integers : In the integrals of the form the following substitutions are useful

(i) If m is odd i.e., power of is odd, put

(ii) If n is odd i.e., power of is odd, put

(iii) If both m and n are even, then we use De–Moivre’s theorem

Some important integrals.

(1) (2)

(3) (4)

(5) (6)

(7) (8)

Reduction formulae for some special cases .

(1) (2)

(3) (4)

(5) (6)

Administrator of IIT.FUNDOOBANDA.COM . Will work relentlessly to improve this portal .