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Calculus 5.2

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5.2 Definite Integrals Greg Kelly, Hanford High School, Richland, Washington When we find the area under a curve by adding rectangles, the answer is called a Rieman ... – PowerPoint PPT presentation

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Title: Calculus 5.2


1
5.2 Definite Integrals
Greg Kelly, Hanford High School, Richland,
Washington
2
When we find the area under a curve by adding
rectangles, the answer is called a Rieman sum.
The width of a rectangle is called a subinterval.
The entire interval is called the partition.
subinterval
partition
Subintervals do not all have to be the same size.
3
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4
If we use subintervals of equal length, then the
length of a subinterval is
The definite integral is then given by
5
Leibnitz introduced a simpler notation for the
definite integral
Note that the very small change in x becomes dx.
6
upper limit of integration
Integration Symbol
integrand
variable of integration (dummy variable)
lower limit of integration
7
We have the notation for integration, but we
still need to learn how to evaluate the integral.
8
In section 5.1, we considered an object moving at
a constant rate of 3 ft/sec.
Since rate . time distance
If we draw a graph of the velocity, the distance
that the object travels is equal to the area
under the line.
After 4 seconds, the object has gone 12 feet.
9
If the velocity varies
Distance
(C0 since s0 at t0)
After 4 seconds
The distance is still equal to the area under the
curve!
Notice that the area is a trapezoid.
10
What if
We could split the area under the curve into a
lot of thin trapezoids, and each trapezoid would
behave like the large one in the previous example.
It seems reasonable that the distance will equal
the area under the curve.
11
We can use anti-derivatives to find the area
under a curve!
12
Lets look at it another way
Then
13
The area of a rectangle drawn under the curve
would be less than the actual area under the
curve.
The area of a rectangle drawn above the curve
would be more than the actual area under the
curve.
14
As h gets smaller, min f and max f get closer
together.
This is the definition of derivative!
initial value
Take the anti-derivative of both sides to find an
explicit formula for area.
15
As h gets smaller, min f and max f get closer
together.
Area under curve from a to x antiderivative at
x minus antiderivative at a.
16
Area
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Example
Find the area under the curve from x1 to x2.
Area from x0 to x1
Area from x0 to x2
Area under the curve from x1 to x2.
18
Example
Find the area under the curve from x1 to x2.
To do the same problem on the TI-89
19
Example
Find the area between the x-axis and the
curve from to .
pos.
neg.
On the TI-89
If you use the absolute value function, you dont
need to find the roots.
p
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