Deck 6: Applications of Integration

Consider the region between the graph of $f ( x ) = \sqrt { x - 1 }$ and the x-axis on the interval [1,5].

-Using four disks or washers approximate the volume of the solid that is obtained by revolving this region around the y-axis.

Consider the region between the graph of $f ( x ) = \sqrt { x - 1 }$ and the x-axis on the interval [1,5].

-Using four disks or washers approximate the volume of the solid that is obtained by revolving this region around the vertical line x = 5.

Consider the region between the graph of $f ( x ) = \sqrt { x - 1 }$ and the x-axis on the interval [1,5].

-Using four disks or washers approximate the volume of the solid that is obtained by revolving this region around the horizontal line y = -1.

Consider the region between the graph of $f ( x ) = x ^ { 2 } + 1$ and the x-axis on the interval [0, 2].

-Use disk /washer method to construct definite integrals to find the volume of the solid that is obtained by revolving this region around the x-axis.

Consider the region between the graph of $f ( x ) = x ^ { 2 } + 1$ and the x-axis on the interval [0, 2].

-Use disk/washer method to construct definite integrals to find the volume of the solid that is obtained by revolving this region around the y-axis.

Consider the region between the graph of $f ( x ) = x ^ { 2 } + 1$ and the x-axis on the interval [0, 2].

-Use disk/washer method to construct definite integrals to find the volume of the solid that is obtained by revolving this region around the vertical line x = -1.

Consider the region between the graph of $f ( x ) = x ^ { 2 } + 1$ and the x-axis on the interval [0, 2].

-Use disk/washer method to construct definite integrals to find the volume of the solid that is obtained by revolving this region around the vertical line x = 2.

Consider the region between the graph of $f ( x ) = x ^ { 2 } + 1$ and the x-axis on the interval [0, 2].

-Use disk/washer method to construct definite integrals to find the volume of the solid that is obtained by revolving this region around the horizontal line y = -1.

Consider the region between the graph of $f ( x ) = x ^ { 2 } + 1$ and the x-axis on the interval [0, 2].

-Use disk/washer method to construct definite integrals to find the volume of the solid that is obtained by revolving this region around the horizontal line y = 5.

Consider the region between the graph of $f ( x ) = 1 - x ^ { 2 }$ and the line y = 2 on the interval [0, 1].

-Use disk/washer method to construct definite integrals to find the volume of the solid that is obtained by revolving this region around the y-axis.

Consider the region between the graph of $f ( x ) = 1 - x ^ { 2 }$ and the line y = 2 on the interval [0, 1].

-Use disk/washer method to construct definite integrals to find the volume of the solid that is obtained by revolving this region around the x-axis.

Consider the region between the graph of $f ( x ) = 1 - x ^ { 2 }$ and the line y = 2 on the interval [0, 1].

-Use disk/washer method to construct definite integrals to find the volume of the solid that is obtained by revolving this region around the vertical line x = 1.

Consider the region between the graph of $f ( x ) = 1 - x ^ { 2 }$ and the line y = 2 on the interval [0, 1].

-Use disk/washer method to construct definite integrals to find the volume of the solid that is obtained by revolving this region around the vertical line x = 2.

Consider the region between the graph of $f ( x ) = 1 - x ^ { 2 }$ and the line y = 2 on the interval [0, 1].

-Use disk/washer method to construct definite integrals to find the volume of the solid that is obtained by revolving this region around the horizontal line y = 2.

Consider the region between the graphs of $f ( x ) = x ^ { 2 }$ and $g ( x ) = 3 x$ on the interval [0, 3].

-Use disk/washer method to construct definite integrals to find the volume of the solid that is obtained by revolving this region around the y-axis.

Consider the region between the graphs of $f ( x ) = x ^ { 2 }$ and $g ( x ) = 3 x$ on the interval [0, 3].

-Use disk/washer method to construct definite integrals to find the volume of the solid that is obtained by revolving this region around the x-axis.

Consider the region between the graphs of $f ( x ) = x ^ { 2 }$ and $g ( x ) = 3 x$ on the interval [0, 3].

-Use disk/washer method to construct definite integrals to find the volume of the solid that is obtained by revolving this region around the horizontal line y = -1.

Consider the region between the graphs of $f ( x ) = x ^ { 2 }$ and $g ( x ) = 3 x$ on the interval [0, 3].

-Use disk/washer method to construct definite integrals to find the volume of the solid that is obtained by revolving this region around the vertical line x = 4.

Consider the region between the graph of $f ( x ) = \sqrt { x - 1 }$ and the x-axis on the interval [1, 5].

-Using four shells approximate the volume of the solid that is obtained by revolving this region around the x-axis.

Consider the region between the graph of $f ( x ) = \sqrt { x - 1 }$ and the x-axis on the interval [1, 5].

-Using four shells approximate the volume of the solid that is obtained by revolving this region around the y-axis.

Consider the region between the graph of $f ( x ) = \sqrt { x - 1 }$ and the x-axis on the interval [1, 5].

-Using four shells approximate the volume of the solid that is obtained by revolving this region around the vertical line x = 5.

Consider the region between the graph of $f ( x ) = 1 - x ^ { 2 }$ and the line y = 2 on the interval [0, 1].

-Use the shell method to construct definite integrals to find the volume of the solid that is obtained by revolving this region around the y-axis.

Consider the region between the graph of $f ( x ) = 1 - x ^ { 2 }$ and the line y = 2 on the interval [0, 1].

-Use the shell method to construct definite integrals to find the volume of the solid that is obtained by revolving this region around the x-axis.

Consider the region between the graph of $f ( x ) = 1 - x ^ { 2 }$ and the line y = 2 on the interval [0, 1].

-Use the shell method to construct definite integrals to find the volume of the solid that is obtained by revolving this region around the vertical line x = 1.

Consider the region between the graph of $f ( x ) = 1 - x ^ { 2 }$ and the line y = 2 on the interval [0, 1].

-Use the shell method to construct definite integrals to find the volume of the solid that is obtained by revolving this region around the vertical line x = 2.

Consider the region between the graph of $f ( x ) = - x + 4$ and the x-axis on the interval [0, 2].

-Use the shell method to construct definite integrals to find the volume of the solid that is obtained by revolving this region around the y-axis.

Consider the region between the graph of $f ( x ) = - x + 4$ and the x-axis on the interval [0, 2].

-Use the shell method to construct definite integrals to find the volume of the solid that is obtained by revolving this region around the x-axis.

Consider the region between the graph of $f ( x ) = - x + 4$ and the x-axis on the interval [0, 2].

-Use the shell method to construct definite integrals to find the volume of the solid that is obtained by revolving this region around the vertical line x = 2.

Consider the region between the graph of $f ( x ) = - x + 4$ and the x-axis on the interval [0, 2].

-Use the shell method to construct definite integrals to find the volume of the solid that is obtained by revolving this region around the horizontal line y = 4.

Find the exact value of the arc length of the function $f ( x ) = 3 - x$ on the interval [1, 4] using a definite integral.

Find the exact value of the arc length of the function $f ( x ) = 2 x + 3$ on the interval [-2, 3] using a definite integral.

Find the exact value of the arc length of the function $f ( x ) = \sqrt { 4 - x ^ { 2 } }$ on the interval [-2, 2] using a definite integral.

Find the exact value of the arc length of the function $f ( x ) = 2 x ^ { 3 / 2 }$ on the interval [0, 2] using a definite integral.

Find the exact value of the arc length of the function $f ( x ) = \ln ( \sin x )$ on the interval [ $\pi$ /4, $\pi$ /2] using a definite integral.

Find the exact value of the arc length of the function $f ( x ) = x ^ { 2 }$ on the interval [-1, 2] using a definite integral.

Find the exact value of the arc length of the function $f ( x ) = 3 \cos x$ on the interval [0, $\pi$ ] using a definite integral.

Use definite integrals to find the area of the surface of revolution obtained by revolving $f ( x ) = 2 x$ around the x-axis on the interval [0, 2].

Use definite integrals to find the area of the surface of revolution obtained by revolving $f ( x ) = \frac { 1 } { x }$ around the x-axis on the interval [1, 4].

Use definite integrals to find the area of the surface of revolution obtained by revolving $f ( x ) = e ^ { x }$ around the x-axis on the interval [-1, 1].

Use definite integrals to find the area of the surface of revolution obtained by revolving $f ( x ) = e ^ { - x }$ around the x-axis on the interval [-1, 2].

Use definite integrals to find the area of the surface of revolution obtained by revolving $f ( x ) = \sin x$ around the x-axis on the interval [ $\pi$ , 2 $\pi$ ].

Use definite integrals to find the area of the surface of revolution obtained by revolving $f ( x ) = \cos x$ around the x-axis on the interval [ $\pi$ /2, 3 $\pi$ /2].

Find the mass of a cylindrical rod with a radius of 5 centimeters and a length of 30 centimeters, made of two metals in such a way that the density of the rod × centimeters from the left end is $\rho ( x ) = 10 - 0.05 x$ grams per cubic centimeter.

Find the mass of a 20-inch rod whose cross section is a 2 × 2 inch square, with density × inches from the left end given by $\rho ( x ) = 3.6 + 0.6 x - 0.03 x ^ { 2 }$ grams per cubic inch.

Find the work required to pump all of the water out of the top of an upright conical tank with top radius 4 feet and height 6 feet.

A cone-shaped water tank with top radius 4 feet and height 6 feet is on an 8-ft-high platform. Find the work done to fill this depot completely through an opening at the bottom of the tank if we pump the water from the ground level.

Find the work required to pump the upper 3 feet of the water out of the top of an upright conical tank with top radius 4 feet and height 6 feet.

Find the work required to pump all of the water out of the top of an upright cylindrical tank with radius 4 feet and height 8 feet.

Find the work required to pump all of the water out of the top of a tank and up to the ground level, given that the tank is an upright cylinder with radius 4 feet and height 8 feet, buried so that its top is 2 feet below the surface.

Find the hydrostatic force exerted on one of the long sides of a rectangular water tank that is 6 feet wide, 10 feet long, and 4 feet deep.

Find the hydrostatic force exerted on a dam in the shape of a trapezoid whose top is 320 feet long, whose base is 200 feet long, and whose height is 80 feet, given that the dam is completely full with water.

Find the hydrostatic force exerted on a dam in the shape of an isosceles triangle whose top is 250 feet wide and whose total height is 100 feet, given that the dam is completely full with water.

Use definite integrals to find the centroid of the region between the graphs of $f ( x ) = 3 x$ and the x-axis on the interval [0, 3].

Use definite integrals to find the centroid of the region bounded by the graphs of $f ( x ) = 2 - x ^ { 2 }$ , $f ( x ) = x$ , and the y-axis.

Use definite integrals to find the centroid of the region between the graph of $f ( x ) = 2 \sqrt { x }$ and $g ( x ) = x$ on the interval [0, 4].

Use separation of variables to solve the differential equation: $$\frac { d y } { d x } = \left( x ^ { 4 } + 2 \right) ^ { 2 }$$

Use separation of variables to solve the differential equation: $$\frac { d y } { d x } = \frac { x - 2 } { \sqrt [ 3 ] { x } }$$

Use separation of variables to solve the differential equation: $$\frac { d y } { d x } = \left( x ^ { 4 } + 2 \right) ^ { 2 } y$$

Use separation of variables to solve the differential equation: $$\frac { d y } { d x } = x ^ { 4 } \cos ^ { 2 } 2 y$$

Use separation of variables to solve the differential equation: $$\frac { d y } { d x } = x e ^ { x ^ { 2 } }$$

Use separation of variables to solve the differential equation: $$\frac { d y } { d x } = x ^ { 3 } e ^ { - 2 y }$$

Use separation of variables to solve the differential equation: $$\frac { d y } { d x } = \frac { 2 + 3 x } { x y }$$

Use separation of variables to solve the differential equation: $$\frac { d y } { d x } = x ^ { 3 } y ^ { 2 }$$

Use separation of variables to solve the differential equation: $$\frac { d y } { d x } = \frac { x y } { x ^ { 2 } + 1 }$$

Use separation of variables to solve the differential equation: $$\frac { d y } { d x } = \frac { 3 } { x ^ { 2 } + 9 }$$

Use separation of variables to solve the differential equation: $$\frac { d y } { d x } = \frac { 5 } { x y }$$

Use separation of variables to solve the differential equation: $$\frac { d y } { d x } = y ( 1 - y )$$

Use separation of variables to solve the differential equation: $$\frac { d y } { d x } = y ^ { 2 } \sin x$$

Use separation of variables to solve the differential equation: $$\frac { d y } { d x } = e ^ { 2 x - y }$$

Use separation of variables to solve the initial value problem: $\frac { d y } { d x } = x y + 2 x + 2 + y$ , $y ( 2 ) = - 1$

Use separation of variables to solve the initial value problem: $\frac { d y } { d x } = y ^ { 3 } \cos x$ , $y \left( \frac { \pi } { 6 } \right) = 1$

Use separation of variables to solve the initial value problem: $\frac { d y } { d x } = \frac { y } { x ^ { 2 } + 1 }$ , $y ( 1 ) = 1$

Use separation of variables to solve the initial value problem: $\frac { d y } { d x } = \frac { x \sqrt { 1 - x ^ { 2 } } } { y }$ , $y ( 0 ) = 1$

Use separation of variables to solve the initial value problem: $\frac { d y } { d x } = y ( 1 - y )$ , $y ( 0 ) = 2$

Use separation of variables to solve the initial value problem: $\frac { d y } { d x } = 3 \sqrt { y }$ , $y ( 3 ) = 4$

Use separation of variables to solve the initial value problem: $\frac { d T } { d t } = 20 - T$ , $T ( 0 ) = 15$

Use separation of variables to solve the initial value problem: $\frac { d N } { d t } = 2 N$ , $N ( 1 ) = e ^ { 4 }$

Use separation of variables to solve the initial value problem: $\frac { d y } { d x } = \frac { x ^ { 2 } } { 1 + x ^ { 3 } }$ , $y ( 0 ) = 3$

Use separation of variables to solve the initial value problem: $\frac { d y } { d x } = e ^ { 2 x - y }$ , $y ( 0 ) = 1$