Volume of Revolution
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volume of solid= <math>{\pi\over 5} units^3</math> | volume of solid= <math>{\pi\over 5} units^3</math> | ||
- | In the example we discussed, the area is revolved about the <math>x</math>-axis. This does not always have to be the case. A funtion can be revolved about any fixed axis. Also, given a different function, to find the volume of revolution, we can substitute it in the place of <math>x^2</math> when evaluating the intergral. Note: we would also need to change the bounds as per the given information. | + | In the example we discussed, the area is revolved about the <math>x</math>-axis. This does not always have to be the case. A funtion can be revolved about any fixed axis. Also, given a different function, to find the volume of revolution, we can substitute it in the place of <math>x^2</math> when evaluating the intergral. Note: we would also need to change the bounds as per the given information. The method discussed in the eample works for all functions revolved about the <math>x</math>-axis |
==References== | ==References== |
Revision as of 09:48, 10 July 2009
- This image is a solid of revolution
Solid of revolution |
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Contents |
Basic Description
This image shows the solid formed after revolving the region bounded by , , and , about the -axisA More Mathematical Explanation
- Note: understanding of this explanation requires: *Pre-calculus and elementary calculus
When finding the volume of revolution of solids, in many cases the problem is not with the calculus, [...]
In general, given a function, we can graph it then revolve the area under the curve between two specific coordinates about a fixed axis to obtain a solid called the solid of revolution. The volume of the solid can then be computed using the disc method.
In the disc method, we imagine chopping up the solid into thin cylindrical plates calculating the volume of each plate, then summing up the volumes of all plates.
For example, let's consider a region bounded by , , and
<-------Plotting the graph of this area,
To find the volume of the solid using the disc method:
Volume of one disc = where - which is the function- is the radius of the circular cross-section and is the thickness of each disc. Using the analogy of the bread, computing the volume of one disc would correspond to computing the volume of one slice of bread. With this in mind, the area of one disc would correspond to the area of a slice of bread, while the thickness of a disc would correspond to the thickness of a slice of bread. To find the total volume of the bread, we would have to sum up the volumes of each of the slices.
Volume of all discs:
Volume of all discs = , with ranging from 0 to 1
If we make the slices infinitesmally thick, the Riemann sum becomes the same as:
Evaluating this intergral,
volume of solid=
In the example we discussed, the area is revolved about the -axis. This does not always have to be the case. A funtion can be revolved about any fixed axis. Also, given a different function, to find the volume of revolution, we can substitute it in the place of when evaluating the intergral. Note: we would also need to change the bounds as per the given information. The method discussed in the eample works for all functions revolved about the -axis
References
Bread image http://mathdemos.gcsu.edu/mathdemos/sectionmethod/sectionmethod.html
Revolving image http://mathdemos.gcsu.edu/mathdemos/sectionmethod/sectionmethod.html
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