area under a curve - swl.k12.oh.us area under a curve.pdf · area under a curve the two big ideas...
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AREA UNDER A CURVE
The two big ideas in calculus are the tangent line problem and the area problem. In the tangent line problem, you saw how the limit process could be applied to the slope of a line to find the slope of a general curve. A second classic problem in calculus is in finding the area of a plane region that is bounded by the graphs of functions. In this case, the limit process is applied to the area of a rectangle to find the area of a general region.
A basic overview of “areas as limits.” In the “limit of rectangles” approach, we take the area under a curve y = f (x) above the interval [a , b] by approximating a collection of inscribed or circumscribed rectangles is such a way that the more rectangles used, the better the approximation. Finally, the number of rectangles is increased without limit and, bingo, we get the area! Now known as integration.Specifically, we are interested in finding the area A of a region bounded by the x‐axis, the graph of a nonnegative function y = f (x) defined on some interval [a, b].
Note: The requirement that f be non‐negative on [a, b] means that no portion of its graph on the interval is below the x‐axis. By using rectangles, we can see that there are three different ways of approximating the area for A. This method is commonly known as Riemann Sums.
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DEFINITION:
Let f be continuous on [a, b] and f(x) ≥ 0 for all x in the interval. We define the area A under the graph on the interval to be:
This is the summation definition of the area between the curve and the xaxis. We use a less conceptual way of estimating the area.
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General Solution Method for inscribed or circumscribed rectangles (Lower and Upper sums):
1. Draw a rough graph of the function over the interval.
2. Use formula to determine each subinterval length.
3. Compute xcoordinates of rectangles at either leftend or rightend.4. Compute the areas of each rectangle (inscribed or circumscribed).5. Find summation of the approximated areas of the rectangles.
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EX #1: Approximate the area under the curve of above the interval [2, 5] by dividing [2, 5] into n = 4 subintervals of equal length and computing
Step 2: Determine subinterval width
Step 3: Compute points of subdivision
Step 4: Since f is increasing the minimum value for f(x) on each subinterval occurs at the left endpoint.
f (c1)=
Height of each rectangle:
f (c2)=
f (c3)= f (c4)=
Step 5: Calculate area of each rectangle.
f (c1) Δx =
f (c4) Δx =
f (c2) Δx =
f (c3) Δx =
INSCRIBED RECTANGLES: Because the graph is increasing, inscribed rectangles will be formed using the left endpoint of each rectangle to calculate the height.
a) the sum of the areas of inscribed rectangles (lower sums)
b) the sum of the areas of circumscribed rectangles (upper sums)
Step 1: Sketch
Step 6: Summation of interval is the sum of the areas of all four rectangles
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CIRCUMSCRIBED RECTANGLES
Step 2: Determine subinterval width
Step 3: Compute points of subdivision
Step 4: Since f is increasing the minimum value for f(x) on each subinterval occurs at the right endpoint.
f (d1)=
Height of each rectangle:
f (d2)=
f (d3)= f (d4)=
Step 5: Calculate area of each rectangle.
f (d1) Δx =
f (d3) Δx = f (d4) Δx =
f (d2) Δx =
Step 6: Summation of interval.
CIRCUMSCRIBED RECTANGLES: Because the function is increasing the circumscribed rectangles will be those with the height calculated from the right endpoint
Step 1: Sketch
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EX #2: Approximate the area under the curve ofabove the interval [0, 2] by dividing the interval into n = 5 subintervals of equal length using inscribed and circumscribed rectangles.