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CALCULUS: AREA UNDER A CURVE. Final Project C & I 336 Terry Kent. “The calculus is the greatest aid we have to the application of physical truth.” – W.F. Osgood. RULE OF 4 . VERBALLY GRAPHICALLY (VISUALLY) NUMERICALLY SYMBOLICLY (ALGEBRAIC & CALCULUS).
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CALCULUS:AREA UNDER A CURVE Final Project C & I 336 Terry Kent “The calculus is the greatest aid we have to the application of physical truth.” – W.F. Osgood
RULE OF 4 VERBALLY GRAPHICALLY (VISUALLY) NUMERICALLY SYMBOLICLY (ALGEBRAIC & CALCULUS) “Calculus is the most powerful weapon of thought yet devised by the wit of man.” – W.B. Smith
VERBAL PROBLEM • Find the area under a curve bounded by the curve, the x-axis, and a vertical line. • EXAMPLE: Find the area of the region bounded by the curve y = x2, the x-axis, and the line x = 1. “Do or do not. There is no try.” -- Yoda
GRAPHICALLY “Mathematics consists of proving the most obvious thing in the least obvious way” – George Polya
NUMERICALLY The area can be approximated by dividing the region into rectangles. Why rectangles? Easiest area formula! Would there be a better figure to use? Trapezoids! Why not use them?? Formula too complex !! “The essence of mathematics is not to make simple things complicated, but to make complicated things simple.” -- Gudder
AREA BY RECTANGLES Exploring Riemann Sums Approximate the area using 5 rectangles. Left-Hand Area = .24 Right-Hand Area = .444 Midpoint Area = .33
Left EndpointInscribed Rectangles n=# rectangles a= left endpoint b=right endpoint
Right EndpointCircumscribed Rectangles n=# rectangles a= left endpoint b=right endpoint
Midpoint n=# rectangles a= left endpoint b=right endpoint
NUMERICALLY AREA IS APPROACHING 1/3 !!
ADDITIONAL EXAMPLES • Approximate the area under the curve using 8 left-hand rectangles for f(x) = 4x - x2, [0,4]. A =
ADDITIONAL EXAMPLES • Approximate the area under the curve using 6 right-hand rectangles for f(x) = x3 + 2, [0,2]. A =
ADDITIONAL EXAMPLES • Approximate the area under the curve using 10 midpoint rectangles for f(x) = x3 - 3x2 + 2, [0,4]. A =
SYMBOLICLY:ALGEBRAIC How could we make the approximation more exact? More rectangles!! How many rectangles would we need? ???
ADDITIONAL EXAMPLES Use the Limit of the Sum Method to find the area of the following regions: • f(x) = 4x - x2, [0,4]. A = 32/3 • f(x) = x3 + 2, [0,2]. A = 8 • f(x) = x3 - 3x2 + 2, [0,4]. A = 8
CONCLUSION The Area under a curve defined as y = f(x) from x = a to x = b is defined to be: “Thus mathematics may be defined as the subject in which we never know what we are talking about, not whether what we are saying is true.” -- Russell
ADDITIONAL EXAMPLES Use Integration to find the area of the following regions: • f(x) = 4x - x2, [0,4]. A =
ADDITIONAL EXAMPLES Use Integration to find the area of the following regions: • f(x) = x3 + 2, [0,2]. A =
ADDITIONAL EXAMPLES Use Integration to find the area of the following regions: • f(x) = x3 - 3x2 + 2, [0,4]. A =
FUTURE TOPICS PROPERTIES OF DEFINITE INTEGRALS AREA BETWEEN TWO CURVES OTHER INTEGRAL APPLICATIONS: VOLUME, WORK, ARC LENGTH OTHER NUMERICAL APPROXIMATIONS: TRAPEZOIDS, PARABOLAS
REFERENCES • CALCULUS, Swokowski, Olinick, and Pence, PWS Publishing, Boston, 1994. • MATHEMATICS for Everyman, Laurie Buxton, J.M. Dent & Sons, London, 1984. • Teachers Guide – AP Calculus, Dan Kennedy, The College Board, New York, 1997. • www.archive,math.utk.edu/visual.calculus/ • www.cs.jsu.edu/mcis/faculty/leathrum/Mathlet/riemann.html • www.csun.edu/~hcmth014/comicfiles/allcomics.html “People who don’t count, don’t count.” -- Anatole France