IMPROPER INTEGRALS AND APPLICATION OF INTEGRATION

IMPROPER INTEGRALS AND APPLICATION OF INTEGRATION

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  IMPROPER INTEGRALS AND APPLICATIONOF INTEGRATION
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   DHRUV MISTRY– 160280106055  SUJAY SHETH – 160280106111  DHRUV SHAH – 160280106106  CHIIRAG MAKWANA – 160280106051  MIHIR PRAJAPATI – 160280106093  RUTVIK PATEL – 160280106080  NIYATI SHAH – 160280106109  SMIT DOSHI – 160280106025  KEVIN SUTARIA – 160280106115  ALPESH PRAJAPATI – 160280106088  ZEEL PATEL – 160280106086  NIYATI SHAH – The Team :
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  Improper Integral TYPE-I: Infinite Limitsof Integration   1 2 1 dx x  1 1 2 1 dx x TYPE-II: Discontinuous Integrand Integrands with Vertical Asymptotes Example Example
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  TYPE-I Infinite Limits    dxxf)(     a a dxxfdxxf )()(       b a b dxxfdxxf a )(lim)(       b aa dxxfdxxf b )(lim)(
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  CONVERGENT AND DIVERGENT1st kind • The improper integrals and are called: – Convergent if the corresponding limit exists. – Divergent if the limit does not exist. ( ) a f x dx   ( ) b f x dx 
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  Example 1 • Determinewhether the integral is convergent or divergent. • Solution: • According to part (a) of Definition 1, we have • The limit does not exist as a finite number and so the • improper integral is divergent.
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  Type-II : DiscontinuousIntegrands
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  • Find • Solution: •We note first that the given integral is improper because • has the vertical asymptote x = 2. • Since the infinite discontinuity occurs at the left endpoint of • [2, 5], we use part (b) of Definition 3:
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  IMPROPER INTEGRALS
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  IMPROPER INTEGRALS
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  Improper Integral OfThird Kind It is a definite integral in which one or both limits of integration are infinite, and the integrand becomes infinite at one or more points within or at the end points of the interval of integration. Thus, it is combination of First and Second Kind.
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  Integral over unbounded intervals: •We have definite integrals of the form and as improper integrals. •If f is continuous on [a,∞],then is a proper integral for any b>a.   a dxxf )( )()( xdxf b a   b a dxxf )( )()()( xdxfdxxf b aa b      
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  If it iscontinuous on and if and both converge , we say that ),(   a dxxf )(   a dxxf )(         a a dxxfdxxfdxxf )()()( If either or both the integrals on RHS of this equation diverge, the integral of f from
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  Application Of Definite Integrals
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  VOLUME Area Between Curves By Slicing Disk Method Washer Method By Cylindrical Shells
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  Areas Between Curves y= f(x) y = g(x)  The area A of the region bounded by the curves y=f(x), y=g(x), and the lines x=a, x=b, where f and g are continuous and f(x) ≥ g(x) for all x in [a,b], is   b a dxxgxfA )]()([
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  General Strategy forArea Between Curves: 1 Decide on vertical or horizontal strips. (Pick whichever is easier to write formulas for the length of the strip, and/or whichever will let you integrate fewer times.) Sketch the curves. 2 3 Write an expression for the area of the strip. (If the width is dx, the length must be in terms of x. If the width is dy, the length must be in terms of y. 4 Find the limits of integration. (If using dx, the limits are x values; if using dy, the limits are y values.) 5 Integrate to find area.
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  Q). Consider thearea bounded by the graph of the function f(x) = x – x2 and x-axis: The volume of solid is: 30/ )5/04/03/0()5/14/23/1( )5/23/( )2( 1 0 533 43 1 0 2          xxx dxxxx 1   1 0 22 )( dxxx © iTutor. 2000-2013. All Rights Reserved
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  Solids of Revolution •A solid generated by revolving a plane area about a line in the plane is called a Solid of Revolution.
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  Volume of SolidOf Revolution can be in : Cartesian Form Parametric Form Polar Form
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  Cartesian Form dxyV b a 2  dxxV d c 2  
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  Parametric Form dt dt dx yV t t 2 2 1   dt dt dx xV t t 2 2 1 
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  Polar Form    drV sin 3 23 2 1      drV cos 3 2 3 2 1  
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  Volume by slicing  b a dxxAV)(
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  The volume ofa solid of known integrable cross-section area A(x) from x = a and x = b is  b a dxxAV )(  General Strategy : 1. Sketch the Solid & a typical Cross-Section. 2. Find the Formula for that Cross –Section area A(x). 3. Find Limits of Integration. 4. Integrate A(x) using Fundamental Theorem.
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  Q). A pyramid3 m high has a square base that is 3 m on a side. The cross-section of the pyramid perpendicular to the altitude x m down from the vertex is a square x m on a side. Find the Volume of the pyramid. •A formula for A(x). The cross- section at x is a square x meters on a side, so its area is 2 )( xxA 
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  Volume by DiskMethod To find the volume of a solid like the one shown in Figure, we need only observe that the cross-sectional area A(x) is the area of a disk of radius R(x), the distance of the planar region’s boundary from the axis of revolution. The area is then So the definition of volume gives :
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  To see howto use the volume of a disk to find the volume of a general solid of revolution, consider a solid of revolution formed by revolving the plane region in Figure about the indicated axis. Figure Disk method
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  Q). Volume ofa Sphere The circle is rotated about the x-axis to generate a sphere. Find its volume. We imagine the sphere cut into thin slices by planes perpendicular to the x-axis. The cross-sectional area at a typical point x between x=a to x=-a 222 ayx 
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  Volume by WasherMethod • The disk method can be extended to cover solids of revolution with holes by replacing the representative disk with a representative washer. • The washer is formed by revolving a rectangle about an axis , as shown in Figure. • If r and R are the inner and outer radii of the washer and w is the width of the washer, the volume is given by • Volume of washer = π(R2 – r2)w. Axis of revolution Solid of revolution
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  If the regionwe revolve to generate a solid does not border on or cross the axis of revolution, the solid has a hole in it (Figure ). The cross-sections perpendicular to the axis of revolution are washers instead of disks. The dimensions of a typical washer are •Outer radius : R(x) •Inner radius : r(x)
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  0 1 2 3 4 1 2 Q). Theregion bounded by and is revolved about the y-axis. Find the volume. 2 y x 2y x The “disk” now has a hole in it, making it a “washer”. If we use a horizontal slice: The Volume of the washer is:  2 2 thicknessR r    2 2 R r dy  outer radius inner radius 2y x 2 y x 2 y x y x 2 y x 2y x   2 24 0 2 y V y dy            4 2 0 1 4 V y y dy         4 2 0 1 4 V y y dy  4 2 3 0 1 1 2 12 y y       16 8 3        8 3   
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  Disks v/s Washers  d c dyyvywV ))]([)](([ 22  d c dyyuV 2 )]([
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  VOLUME BY CYLINDRICAL SHELL
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  36 General Strategies : •Sketch the graph over the limits of integration • Draw a typical shell parallel to the axis of revolution • Determine radius, height, thickness of shell • Volume of typical shell • Use integration formula 2 radius height thickness    2 b a Volume radius height thickness   
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  VOLUMES BY CYLINDRICALSHELLS Cylinder h r2 rh2Areasurface  Shell rrh 2volumeshell r Cylinder h r2 )(),( 122 1 12 rrrrrr 
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  Q). Find thevolume of the solid obtained by rotating about the y-axis the region between y = x and y = x2. • We see that the shell has radius x, circumference 2πx, and height x - x2. • Thus, the volume of the solid is:      1 2 0 1 2 3 0 13 4 0 2 2 2 3 4 6 V x x x dx x x dx x x                  
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  Method Axis ofrotation Formula Disks and Washers The x-axis The y-axis Cylindrical Shells The x-axis The y-axis