This document discusses various topics related to integration including indefinite and definite integrals, power rules, properties of integrals, integration by parts, u-substitution, and definitions. Some key points covered are:
- Integration was developed independently by Newton and Leibniz in the late 17th century.
- The indefinite integral finds an antiderivative, while the definite integral evaluates the area under a function between bounds.
- Common integration techniques include power rules, integration by parts, and u-substitution.
- Integration rules and properties allow integrals to be transformed and simplified.
5. The indefinite integral ∫f(x)dx is defined as a
function g such as its derivative
D.[g(x)]=f(x).
The definite integral is a number whose
value depends on the function f and the numbers a
and b, and it is defined as the limit of Riemann
sum.
he arbitrary constant c is
called a constant of integration .
6. The derivative of a constant is 0. However, when
you integrate, you should consider that there is a
possible constant involved, but we don’t know what
it is for a particular problem. Therefore, you can
just use C to represent value.
To solve for C, you will be given a problem that
gives you the y(0) value. Then you can plug the 0
in for x and the y(0) value for y.
7. Where,
C = Constant of integration
u = Function
n = Power
du = Derivative
The equation is
∫ (u^(n)) du = {(u^(n+1)) / (n+1)} +C
11. If the functions are not related then use integration
by parts.
Is a rule that transforms the integral of products of
function into other functions .
The equation is ∫ u dv = uv -∫ u du . .
12. 1. ∫ x e^(x) dx
Let, x = u
.‧. dx = du
e^(x) dx = dv
.‧. ∫ dv = ∫ e^(x) dx
= e^(x) + c
Now,
we know,
∫ u dv = uv - ∫ u du
= x * e^(x) - ∫ e^(x) dx
= x e^(x) – e^(x) + c
= e^(x) {x-1} + c.
(ANS)
2. ∫ x sin(x) dx
Let, x = u
.‧. du = dx
sin(x) dx = dv
.‧. v = { - cos(x)}
Now,
we know,
∫ u dv = uv - ∫ u du
= x*{ - cos(x)} - ∫ { - cos(x)} dx
= - x cos(x) + ∫ cos(x) dx
= - x cos(x) + sin(x )+ c.
(ANS)
13. oThe method of substitution can be motivated by
examining the chain rule from the view point of anti-
differentiation.
o This is used when there are two algebraic functions and
one of them is not the derivative of the other.
14. 1. ∫{(x^(2) +1)^50 * 2x} dx
Let, u = x^(2) + 1
.‧. du = 2x dx
Now,
∫{((x^(2) + 1)^50) *
2x} dx
= ∫ (u^50) du
= (u^51) / 51 + C
= (x^(2) + 1)^51 /51
+C.
(ANS)
2. ∫ cos 5x dx
Let, u = 5x
.‧. du = 5 dx
.‧. dx = (1/5) du
Now,
∫ cos 5x dx
= ∫ (cos u) * (1/5) du
= (1/5) ∫ cos u du
= (1/5) sin u + C
=(1/5) sin 5x + C.
(ANS)