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Title: Integration basics: notes for mastering!
Description: Applicable for A-level school students & first year engineering/maths students; these notes will assist you with tackling all types of integration problems. The Four Laws of Integration are highlighted, and mastering each of them will make integration problem solving more enjoyable.
Description: Applicable for A-level school students & first year engineering/maths students; these notes will assist you with tackling all types of integration problems. The Four Laws of Integration are highlighted, and mastering each of them will make integration problem solving more enjoyable.
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Compiled by: D
...
van der Berg
Understanding Integration
Introduction
What is integration?
β’
Reverse differentiation (anti-differentiation)
Why use it?
β’
Used to find volumes, area and central points
...
β« (2π₯π₯ (3+1) + 1π₯π₯ (2+1) + 7π₯π₯ (1+1) )ππππ
β« οΏ½(2 Γ· 4)π₯π₯ 4 + (1 Γ· 3)π₯π₯ 3 + (7 Γ· 2)π₯π₯ 2 οΏ½ππππ
1
IMPORTANT NOTE:
1
7
= β΄ ππ β² (π₯π₯) = π₯π₯ 4 + π₯π₯ 3 + π₯π₯ 2
2
3
2
You can check your answer by finding its derivative!
Compiled by: D
...
van der Berg
Rules of integration
Includes 4 major rules (ISTP)
1
...
3
...
ο depends on the given functions
Inspection
Substitution
Trigonometric substitution
Parts
1
...
By Substitution:
2
...
When a function and its derivative appear in the integral:
Let π’π’ = ππ(π₯π₯)
β« ππ(π₯π₯)
...
2
...
J
...
By Trigonometric Substitution:
3
...
Compound-angle formulae
Integrating a product of trigonometric functions:
β« sin 4π₯π₯ cos 3π₯π₯ ππππ
and
(1) sin(4π₯π₯ + 3π₯π₯) = sin 4π₯π₯ cos 3π₯π₯ + cos 4π₯π₯ sin 3π₯π₯
(2) sin(4π₯π₯ β 3π₯π₯) = sin 4π₯π₯ cos 3π₯π₯ β cos 4π₯π₯ sin 3π₯π₯
Add these two expansions (1) and (2):
β΄ sin 7π₯π₯ + sin π₯π₯ = 2 sin 4π₯π₯ cos 3π₯π₯
1
(our substitution)
β΄ sin 4π₯π₯ cos 3π₯π₯ = 2 (sin 7π₯π₯ + sin π₯π₯)
So,
β« sin 4π₯π₯ cos 3π₯π₯ ππππ
1
= 2 β« (sin 7π₯π₯ + sin π₯π₯) ππππ
=
β cos 7π₯π₯
14
β
cos π₯π₯
2
+ ππ
Shortcut rules to study:
1
(a) sin π΄π΄ cos π΅π΅ = 2 [sin(π΄π΄ + π΅π΅) + sin(π΄π΄ β π΅π΅) ]
1
(b) sin π΄π΄ sin π΅π΅ = 2 [cos(π΄π΄ β π΅π΅) β cos(π΄π΄ + π΅π΅) ]
1
(c) cos π΄π΄ cos π΅π΅ = 2 [cos(π΄π΄ β π΅π΅) + cos(π΄π΄ + π΅π΅) ]
3
...
Double-angle formulae
Useful for squared trigonometric functions:
β« sin2 π₯π₯ ππππ
or
β« cos 2 π₯π₯ ππππ
We use the following rules:
1
(a) sin2 π₯π₯ = 2 (1 β cos 2π₯π₯)
1
(b) cos2 π₯π₯ = 2 (1 + cos 2π₯π₯)
Derivation from
and from
cos 2π₯π₯ = 2 cos2 π₯π₯ β 1
sin2 π₯π₯ + cos2 π₯π₯ = 1
Compiled by: D
...
van der Berg
4
...
That is, the one is NOT the
derivative of the other:
β« ππ(π₯π₯)ππ(π₯π₯)ππππ
Developed from the reverse product rule for differentiation
...
Carefully consider this:
Option (1):
if we make our choices as below:
then ππππ = cos π₯π₯π₯π₯π₯π₯
π’π’ = sin π₯π₯,
And ππππ = π₯π₯π₯π₯π₯π₯,
then π£π£ =
Substitute our choices into
β΄ β« π₯π₯ sin π₯π₯ ππππ =
Option (2):
π₯π₯ 2
2
π₯π₯ 2
π₯π₯ 2
2
(we integrate dv)
β« π’π’π’π’π’π’ = π’π’π’π’ β β« π£π£π£π£π£π£:
sin π₯π₯ β β« οΏ½ 2 cos π₯π₯οΏ½ ππππ
ο this is complicated!! Try Option (2)
if we make our choices as below:
π’π’ = π₯π₯, then ππππ = 1ππππ
And ππππ = sin π₯π₯ ππππ,
then π£π£ = β cos π₯π₯
β΄ β« π₯π₯ sin π₯π₯ ππππ = βπ₯π₯ cos π₯π₯ β β« (β cos π₯π₯)ππππ
=
βπ₯π₯ cos π₯π₯ β sin π₯π₯ + ππ
Compiled by: D
...
van der Berg
Another useful rule β Reverse Chain Rule:
Used for expressions with difficult exponent-based brackets:
1
β« (π₯π₯ 2 β 1)2 ππππ
Example
1
...
Divide entire expression by new exponent
3
2
3
...
sin 5ππ ππππ
(d) β« οΏ½π¦π¦οΏ½π¦π¦ + 3οΏ½ ππππ
(e) β« π₯π₯ 2 sinπ₯π₯ ππππ
(f) β« οΏ½
π₯π₯+1
οΏ½ ππππ
β2π₯π₯β1
(g) β« π₯π₯ 2 (π₯π₯ 3 β 1)5 ππππ
Check your answers by finding its derivative
Title: Integration basics: notes for mastering!
Description: Applicable for A-level school students & first year engineering/maths students; these notes will assist you with tackling all types of integration problems. The Four Laws of Integration are highlighted, and mastering each of them will make integration problem solving more enjoyable.
Description: Applicable for A-level school students & first year engineering/maths students; these notes will assist you with tackling all types of integration problems. The Four Laws of Integration are highlighted, and mastering each of them will make integration problem solving more enjoyable.