11.02 Evaluate areas using geometry
Calculate geometrically, the area bounded by the following functions and the x-axis over the given domain:
2 \leq x \leq 5
0 \leq x \leq 7
0 \leq x \leq 4
0 \leq x \leq 9
Calculate geometrically, the exact value of the following definite integrals:
\int_{0}^{6} \left(6 - x\right) dx
\int_{0}^{12} f \left( x \right) dx
\int_{0}^{16} f \left( x \right) dx
\int_{1}^{8} \left(10 - x\right) dx
\int_{3}^{5} \left( 2 x + 1\right) dx
\int_{0}^{16} f \left( x \right) dx
\int_{ - 6 }^{6} \sqrt{36 - x^{2}} dx
\int_{0}^{6} \sqrt{36 - x^{2}} dx
\int_{0}^{16} f \left( x \right) dx
\int_{0}^{12} \sqrt{36 - \left(x - 6\right)^{2}} dx
For each of the following functions:
Sketch a graph of f \left( x \right).
Hence, calculate geometrically the area bounded by the curve and the x-axis over the given domain:
f \left( x \right) = 6 - 6 x for 0 \leq x \leq 1
f \left( x \right) = 3 x + 4 for 0 \leq x \leq 3
f(x)=\begin{cases} x & \text{for } 0\leq x \lt 4\\ 8-x & \text{for } 4\leq x\leq 8 \end{cases}
f(x)=\begin{cases} 2x & \text{for } 0\leq x \leq 3\\ 6 & \text{for } 3\lt x\lt 6\\ 18-2x & \text{for } 6\leq x \leq 9 \end{cases}
Consider the function f \left( x \right) = x^{2} - 3 x + 10.
For each of the following intervals, state whether the right endpoint approximation method will underestimate or overestimate the area under the curve. Explain your answer.
\left[ 3, 8 \right]
\left[ -6, -2 \right]
Consider the function f \left( x \right) = x^{2} + 5.
For each of the following intervals, state whether the left endpoint approximation method will underestimate or overestimate the area under the curve. Explain your answer.
\left[ 2, 6 \right]
\left[ -5, -1 \right]
Consider the function f \left( x \right) = 10 e^{x}.
State the approximation method that will give an underestimate of the true area on any given interval. Explain your answer.
Consider the function f \left( x \right) = -3 x^{2} - 24 x + 1.
State whether the right endpoint approximation to the area will overestimate or underestimate on the following intervals.
\left[ -10, -5 \right]
\left[ -4, 2 \right]
\left[ 0, 2 \right]
\left[ -6, -4 \right]
State whether the left endpoint approximation to the area will overestimate or underestimate on the following intervals.
\left[ -10, -5 \right]
\left[ -4, 2 \right]
\left[ 0, 2 \right]
\left[ -6, -4 \right]
The function f \left( x \right) = 5 x is defined on the interval \left[0, 6\right].
Graph f \left( x \right).
Find the area under f \left( x \right) by partitioning \left[0, 6\right] into 3 sub-intervals of equal length using:
Left endpoint approximation
Right endpoint approximation
Find the area under f \left( x \right) by partitioning \left[0, 6\right] into 6 sub-intervals of equal length using:
Left endpoint approximation
Right endpoint approximation
Find the actual area under the curve on the interval \left[0, 6\right].
The function f \left( x \right) = - 4 x + 12 is defined on the interval \left[0, 3\right].
Graph f \left( x \right).
Find the area under f \left( x \right) by partitioning \left[0, 3\right] into 3 sub-intervals of equal length using:
Left endpoint approximation
Right endpoint approximation
Find the area under f \left( x \right) by partitioning \left[0, 3\right] into 6 sub-intervals of equal length using:
Left endpoint approximation
Right endpoint approximation
Find the actual area under the curve on the interval \left[0, 3\right].
The interval \left[0, 8\right] is partitioned into 4 sub-intervals \left[0, 2\right], \left[2, 4\right],\left[4, 6\right], and \left[6, 8\right].
Find the area under the curve on the interval \left[0, 8\right] using:
Left endpoint approximation
Right endpoint approximation
Use left endpoint approximation to find \int_{1}^{9} 2 x^{2} dx by using 4 rectangles of equal width.
Use right endpoint approximation to find \int_{1}^{5} \dfrac{1}{x} dx by using 4 rectangles of equal width.
Give your answer as a simplified fraction.
Approximate \int_{3}^{15} \left( 4 x + 6\right) dx by using 4 rectangles of equal width and using the method:
Left endpoint approximation
Right endpoint approximation
Use technology to find the exact value of the following definite integrals:
Consider the function f \left( x \right) = 0.5 x^{2}.
Complete the table to estimate the area between the function and the x-axis for \\1 \leq x \leq 3 using the left endpoint approximation method. Round your answers to three decimal places.
| n | 5 | 10 | 100 | 1000 | 10\,000 |
|---|---|---|---|---|---|
| A_L \text{ units}^2 |
Use technology to evaluate \int_{1}^{3} 0.5x^2 \ dx and hence confirm that the exact area is the limit of A_L as n gets larger.
Consider the function f \left( x \right) = \sqrt{4 - x^{2}}.
Complete the table to estimate the area between the function and the x-axis for \\0 \leq x \leq 2 using the right endpoint approximation method. Round your answers to five decimal places.
| n | 5 | 10 | 100 | 1000 |
|---|---|---|---|---|
| A_R \text{ units}^2 |
Use technology to evaluate \int_{0}^{2} \sqrt{4 - x^{2}} \ dx and hence confirm that the exact area is the limit of A_R as n gets larger.
Consider the function f \left( x \right) = - x^{2} + 3 x.
Sketch a graph of f(x).
State the x-values that define the region bounded by the curve and the x-axis. Write your answer as an inequality.
Complete the table to estimate the area of the region bounded by the function and the \\x-axis using the right endpoint approximation method. Round your answers to four decimal places.
| n | 5 | 10 | 100 | 1000 | 10\,000 |
|---|---|---|---|---|---|
| A_R \text{ units}^2 |
Use technology to confirm that the exact area is the limit of A_R as n gets larger.