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Integral Review Megan Bryant 4/28/2015. Bernhard Riemann  Bernhard Riemann (1826-1866) was an influential mathematician who studied under Gauss at the.

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Presentation on theme: "Integral Review Megan Bryant 4/28/2015. Bernhard Riemann  Bernhard Riemann (1826-1866) was an influential mathematician who studied under Gauss at the."— Presentation transcript:

1 Integral Review Megan Bryant 4/28/2015

2 Bernhard Riemann  Bernhard Riemann (1826-1866) was an influential mathematician who studied under Gauss at the University of Gottingen.  He made major contributions to mathematics including complex variables, number theory, and the foundations of geometry.  We use Riemann’s definition of the definite integral.

3 Definite Integrals

4 Integration Terms  Integrand: f(x)  Limits of Integration: a,b  Upper Limit: b  Lower Limit: a

5 Riemann Sums

6 Left Riemann Sums  For a left Riemann sum, the endpoints that are used to construct your ‘rectangles’ are a, x 1,…,b-1, but do not include b (the right endpoint).  Left Riemann sums underestimate the area under the curve.

7 Right Riemann Sums  For a right Riemann sum, the endpoints that are used to construct your ‘rectangles’ are a+1, x 1,…,b, but do not include a (the left endpoint).  Right Riemann sums over estimate the area under the curve.

8 Mid Riemann Sums  For a mid Riemann sum, the endpoints that are used to construct your ‘rectangles’ are (a + x 1 )/2, (x 2 + x 3 )/2 …,(x b-1 +b)/2  Mid Riemann sums provide a balance between under (left) and over (right) estimating the area.

9 Left, Right, and Mid Points

10 Riemann Sum Example  Evaluate the Riemann sum for f(x) = x 3 -6x taking the sample points to be left endpoints and a = 0, b = 3, and n = 6.

11 Riemann Example: Find the Width

12 Riemann Example: Graph the Rectangles Remember, we are looking for the left Riemann sum with n=6 and a width of ½.

13 Riemann Sum: Final Area  To calculate the Riemann sum, find the area of all 6 rectangles and add them together.

14 Riemann Sum: Right  Now, let’s look at the right Riemann sum.  We will still have n = 6 and thus our width will remain the same.

15 Riemann Sums: Right Area Is this a better estimate? Why or why not? Is there a better way?

16 Mid Riemann Sum  Let’s try the Midpoint. We still have n = 6 and a width of ½.

17 Mid Riemann Sum Area This is a better estimate than the left and right Riemann sums separately. Midpoints often give a better estimate of the area under the curve.

18 First Fundamental Theorem of Calculus  The fundamental theorem of calculus is a theorem that links the concept of the derivative of a function with the concept of the function’s integral.  The first fundamental theorem of calculus is that the definite integration of a function is related to its anti derivative.

19 Example 1

20

21 Example 2

22

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