![Integration- the process of evaluating an
indefinite integral or a definite integral
The indefinite integral f(x)dx is
defined as a function g such that its
derivative Dx[g(x)]=f(x)](https://image.slidesharecdn.com/h2kya7flrxkdwszbdd7z-signature-419a05f0d36132b6bad00ab46894cbfc9de2a91b3aaefe89ae8e916bd9cd3747-poli-170820085338/85/Integration-and-its-basic-rules-and-function-4-320.jpg)
![Example 2
(integration by parts)
2
1 x(e^3x) dx= u= x dv= e3x
dx
du= dx v= 1/3 e3x
Plugged into the formula gives you:
1/3x e3x
– 1/3 e3x
dx=
2
[1/3x e3x
– 1/9 e3x
]1 = [(2/3e6
-1/9 e6
) – (1/3e3x
-1/9e3x
)]=
5/9e6
– 2/9e3x
∫
∫](https://image.slidesharecdn.com/h2kya7flrxkdwszbdd7z-signature-419a05f0d36132b6bad00ab46894cbfc9de2a91b3aaefe89ae8e916bd9cd3747-poli-170820085338/85/Integration-and-its-basic-rules-and-function-10-320.jpg)
![Example 1
(u substitution)
x dx u=
x=(u2
- 1)/(2)
udu= dx
= (u2
-1/2)(u)(udu)
= ½[(u5
/5)-(u3
/3)] + C
=1/10(2x+1)5/2
- 1/6(2x+1)3/2
+ C
∫ 12 +x 12 +x
∫](https://image.slidesharecdn.com/h2kya7flrxkdwszbdd7z-signature-419a05f0d36132b6bad00ab46894cbfc9de2a91b3aaefe89ae8e916bd9cd3747-poli-170820085338/85/Integration-and-its-basic-rules-and-function-13-320.jpg)
![Example 1
(definite integration)
/2
0 x cosx dx= u= x dv= cosx dx
du= dx v= sinx
Plugged into the formula gives you:
/2
x sinx - sinx dx= [(x sinx) +
(cosx)] 0 =
( /2 + 0) – (0 + 1) =
Final Answer:
∫
∫](https://image.slidesharecdn.com/h2kya7flrxkdwszbdd7z-signature-419a05f0d36132b6bad00ab46894cbfc9de2a91b3aaefe89ae8e916bd9cd3747-poli-170820085338/85/Integration-and-its-basic-rules-and-function-28-320.jpg)
![Example 2
(definite integration)
4
x dx u=
0
x= -u2
+ 4
dx= -2udu
(-u2
+ 4)u(-2udu)
(2u4
- 8u2
)du 4
-8/3u3
+ 2/5u5
= [-8/3(4-x)3/2
+ 2/5(4-x)5/2
]0
Final solution: (-64/3 + 64/5) – (0)= -320 + 192/15 = -128/5
x−4 x−4∫](https://image.slidesharecdn.com/h2kya7flrxkdwszbdd7z-signature-419a05f0d36132b6bad00ab46894cbfc9de2a91b3aaefe89ae8e916bd9cd3747-poli-170820085338/85/Integration-and-its-basic-rules-and-function-29-320.jpg)
Integration and its basic rules and function.
- 1. By: Chris Tuggle and Ashley Spivey Period: 1 http://www.musopen.org/sheetmusic.php?type=sheet&id=2456
- 2. History of integration -Archimedes is the founder of surface areas and volumes of solids such as the sphere and the cone. His integration method was very modern since he did not have algebra, or the decimal representation of numbers -Gauss was the first to make graphs of integrals, and with others continued to apply integrals in the mathematical and physical sciences. -Leibniz and Newton discovered calculus and found that differentiation and integration undo each other
- 3. How integration applies to the real world -Integration was used to design the Petronas Towers making it stronger -Many differential equations were used in the designing of the Sydney Opera House -Finding the volume of wine casks was one of the first uses of integration -Finding areas under curved surfaces, Centres of mass, displacement and Velocity, and fluid flow are other uses of integration
- 4. Integration- the process of evaluating an indefinite integral or a definite integral The indefinite integral f(x)dx is defined as a function g such that its derivative Dx[g(x)]=f(x)
- 5. 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 a riemann sum Indefinite integral involves an arbitrary constant; for instance, x2 dx= x3 + c The arbitrary constant c is called a constant of integration
- 6. Why we include C -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 the 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. Power Rule 1 1 n n u u du C n + = + +∫ C = Constant of integration u = Function n = Power du = Derivative
- 8. Integration by parts -Is a rule that transforms the integral of products of functions into other functions -If the functions are not related then use integration by parts The equation is u dv= uv- u du∫ ∫
- 9. Example 1 (integration by parts) x cosx dx= u=x dv=cosx dx du=dx v= -sinx Then you plug in your variables to the formula: u dv= uv- u du Which gives you: Xsinx + sinx dx= X sinx + cosx + c ∫ ∫ ∫∫
- 10. Example 2 (integration by parts) 2 1 x(e^3x) dx= u= x dv= e3x dx du= dx v= 1/3 e3x Plugged into the formula gives you: 1/3x e3x – 1/3 e3x dx= 2 [1/3x e3x – 1/9 e3x ]1 = [(2/3e6 -1/9 e6 ) – (1/3e3x -1/9e3x )]= 5/9e6 – 2/9e3x ∫ ∫
- 11. Example 3 (natural log) Formula: (1/x)dx= lnIxI + C lnx dx= u= lnx dv= dx du= (1/x) dx v= x Plugged into the formula gives you: x lnx - dx= Final answer: x lnIxI – x + c ∫ ∫ ∫
- 12. U substitution - This is used when there are two algebraic functions and one of them is not the derivative of the other
- 13. Example 1 (u substitution) x dx u= x=(u2 - 1)/(2) udu= dx = (u2 -1/2)(u)(udu) = ½[(u5 /5)-(u3 /3)] + C =1/10(2x+1)5/2 - 1/6(2x+1)3/2 + C ∫ 12 +x 12 +x ∫
- 14. Example 2 (u substitution) x/ dx u= x= u2 + 3 dx= 2udu (u2 +3/u) x (2udu) = 2 (u2 + 3) du =2/3u3 + 6u + C =(2/3)(x-3)3/2 + 6(x-3)1/2 + C 3−x 3−x ∫ ∫
- 16. Example 1 (trigonometric substitution) ∫x(sec^2)dx u= x dv= (sec^2)xdx du= dx v= tanx =xtanx- tanxdx =xtanx + lnIcosxI + C ∫
- 17. Example 2 (trigonometric substitution) sin / dx U= Du= dx N= -1/2 Solution: -2cos + C ∫ x x x x
- 18. Example 3 (trigonometric substitution) cosx/ dx u= 1 + sinx du= cosxdx n= -1/2 sin3 xcos4 xdx= sin2 xsinxcos4 xdx= (1 - cos2 x)sinxcos4 xdx= sinxcos4 xdx - sinxcos6 xdx= Final solution: -1/5cos5 x + 1/7cos7 x + C xsin1+
- 19. Integrating powers of sine and cosine -Integrating odd powers -Integrating even powers -Integrating odd and even powers
- 20. Integrating odd powers ∫sin5 xdx sin3 xsin2 xdx 1-cos2 xsin3 xdx 1-cos2 xsinxsin2 xdx (1-cos2 x)2 sinxdx (1-2cos2x + cos4 x) sinxdx sinxdx- 2cos2 xsinxdx + cos4 xsinxdx Final solution: -cosx – 2/3cos3 x – 1/5cos5 x + C ∫ ∫ ∫ ∫ ∫
- 21. Integrating even powers sin4 1/2xcos2 1/2xdx= (1-cosx/2)2 (1/cosx/2)dx= (1-cosx)(1-cos2 x)dx= (1-cos2 x – cosx + cos3 x)dx= 1/8 dx – 1/8 (1 + cos2x/2)dx - 1/8 cosxdx+ 1/8 cos2 xcosxdx= 1/8 dx – 1/16 dx – 1/16 cos2xdx – 1/8 cosxdx + 1/8 cosxdx – 1/8 sin2 cosxdx= 1/6 dx – 1/16 cos2xdx – 1/8 sin2 xcosxdx Final solution: 1/16x – 1/32sin2x – 1/24sin3 x + C ∫ ∫ ∫ ∫ ∫ ∫ ∫ ∫∫∫ ∫∫ ∫ ∫ ∫ ∫∫
- 22. Integrating odd and even powers sin3 6xcos2 6xdx= sin6xsin2 6xcos2 6xdx= sin6x(1- cos2 6x)cos2 6xdx= -1/6 sin6xcos2 6xdx - sin6xcos4 6xdx= u= cos6x du= -6sin6x n= 2 Final solution: -1/18cos3 6x + 1/30cos5 x + C ∫ ∫∫ ∫ ∫
- 23. Integration by partial fractions Used when: -Expressions must be polynomials -Power rule should be used at some point -The denominator is factorable -Power or exponent represents how many variables or fractions there are
- 24. Example 1 (partial fractions) (6x2 - 2x – 1)/(4x3 – x) dx (A/x) + (B/2x - 1) + (C/(2x+1) A(4x2 -1)----4Ax2 - A Bx(2x + 1)--2Bx2 + Bx C(2x-1)------2Cx2 – Cx 2A + B + C= 3 B – C= -2 (1/x)dx + -1/2 (dx/2x-1) + 3/2 (dx/2x+1) A=1 Final solution: lnIxI – 1/4lnI2x-1I + 3/4lnI2x+1I + C B + C=1 +B – C= -2 B= -1/2 C= 3/2 ∫ ∫∫∫
- 25. Example 2 (partial fractions) (x+1)/(x2 – 1)dx A(X+1) B(X-1) A/(x-1) + B/(x+1) AX+A BX-B A + B= 0 + A – B= 1 2A=1 A=1/2 B=-1/2 1/2 (1/x-1)dx- ½ (1/x+1)dx Final solution: 1/2lnIx-1I – 1/2lnIx+1I + C ∫ ∫ ∫
- 26. Example 3 (partial fractions) (3x2 - x + 1)/ (x3 - x2 )dx Ax(x-1)--- Ax2 - Ax B(x-1)-----Bx - B Cx2 --------Cx2 A + C=3 +-A + B=-1 B=-1 -1/x2 dx + 3/x-1 dx ∫ ∫ ∫
- 27. Definite integration -This is used when the numerical bounds of the object are known
- 28. Example 1 (definite integration) /2 0 x cosx dx= u= x dv= cosx dx du= dx v= sinx Plugged into the formula gives you: /2 x sinx - sinx dx= [(x sinx) + (cosx)] 0 = ( /2 + 0) – (0 + 1) = Final Answer: ∫ ∫
- 29. Example 2 (definite integration) 4 x dx u= 0 x= -u2 + 4 dx= -2udu (-u2 + 4)u(-2udu) (2u4 - 8u2 )du 4 -8/3u3 + 2/5u5 = [-8/3(4-x)3/2 + 2/5(4-x)5/2 ]0 Final solution: (-64/3 + 64/5) – (0)= -320 + 192/15 = -128/5 x−4 x−4∫