Volume Derivation - Sphere

Category: Integral Calculus, Solid Geometry

"Published in Newark, California, USA"

Given the equation of the sphere below:

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Prove that the volume of sphere is  ⁴/₃ π r³                                                      

Solution:

From the given figure, let's consider only the ¹/₈ of the sphere to get the volume and then multiply it by 8 later. 

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Image that there are many tiny cubes that will fill-up the section of a sphere. Let's assume that the dimensions of the cubes, dx, dy, and dz are perfect enough to fill-up the section of a sphere. 

dV = dx dy dz

Integrate on both sides of the equation, we have

Next, let's assign the lower and upper limits for each integrals.

Along the x-axis, let's consider the largest cross section of a sphere at xy plane, the cube is moved from 0 to r, and so the lower limit is 0 and the upper limit is r.

Along the y-axis, let's consider the largest cross section of a sphere at xy plane. The cube is moved from 0 to the surface of the cross section. The cross section is a circle with an equation: x² + y² = r² where z² = 0. Solve for the value of y, we have

Therefore, the lower limit is 0 and the upper limit is 

Along the z-axis, let's consider the largest cross section of a sphere at xy plane. The cube is moved from the cross section of a sphere at xy plane to the surface of a sphere. From the equation of the sphere: x² + y² + z² = r², solve for the value of z, we have

Therefore, the lower limit is 0 and the upper limit is

The volume of a sphere can be written as

The above equation can also be written as

Integrate first with respect to z, consider x and y are the constants

   let a² = r²- x²

   and u² = y²

Using the integration formula,

Integrate with respect to y, consider x as a constant. Therefore,

Finally, integrate with respect to x, we have

 

Therefore, the volume of a sphere is 

Proving Trigonometric Identities - Double Angle

Category: Trigonometry

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Prove the trigonometric identity for

Solution:

In proving of trigonometric identities, you must choose the more complicated side of the equation and then simplify as much as you can until it is equal to the other side of the equation. In this case, consider the given equation

Let's expand and then simplify the left side of the equation as follows

but 

The equation becomes

Therefore,

Approximation - Error Problem

Category: Differential Calculus, Solid Geometry

"Published in Newark, California, USA"

The altitude of a certain right circular cone is the same as the radius of the base, and is measured as 5 inches with a possible error of 0.02 inch. Find approximately the percentage error in the calculated value of the volume.

Solution:

From the description of a problem, it is an approximation and error problem because it involves the difference of the dimensions of a right circular cone as well  as the difference of the volume. 
 

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The volume of a right circular cone is calculated as

but r = h

Take the differentials on both sides, we have

The original volume of the right circular cone is calculated as

Therefore, the percent of error is calculated as

% Error = (± 0.012)(100) = 1.2%