How to determine height of the cylinder with maximum volume engraved in a sphere with radius RR?

3 Answers
Walker P
Apr 26, 2017

h=sqrt((4R^2)/3h=4R23 where RR is the radius of the sphere

Explanation:

This problem is really interesting, but will definitely require some visualization to figure out. Let's start by using the formula for the volume of a cylinder:
enter image source here
We know that the area of a circle is:

A=pir^2A=πr2

Therefore, the volume is:

V=pir^2hV=πr2h

This cylinder, however, is engraved in a sphere. Its cross-sectional area and height are, therefore, restricted by the sphere as shown below:
enter image source here
Now, imagine cutting the sphere in half two times. After the first and second cuts, we will see:
enter image source here
If we focus on the cross section in the last cut, we can use the Pythagorean theorem to find a relationship between 1/2h12h, rr, and RR. Specifically,

(1/2h)^2+r^2=R^2(12h)2+r2=R2
h^2/4+r^2=R^2h24+r2=R2

Solving for rr, we get:
r^2=R^2-h^2/4r2=R2h24

Now that we have r^2r2 as a function of hh, plug it back into the original volume equation:

V=pi(R^2-h^2/4)*hV=π(R2h24)h

Simplify the expression:

V=piR^2h-pih^3/4V=πR2hπh34

Now that we have the volume of the cylinder expressed as a function of its height, hh, take the derivative of the volume function with respect to hh and set it equal to 0.

(Recall: Local maximum of a function is located where its derivative equals 0).

(dV)/(dh)=piR^2-3h^2/4dVdh=πR23h24
0=piR^2-(3h^2)/40=πR23h24
-piR^2=-(3h^2)/4πR2=3h24
-4/(3pi)*piR^2=-(3pih^2)/4*-4/(3pi)43ππR2=3πh2443π
(4R^2)/3=h^24R23=h2

Therefore, the value of hh that maximizes the volume of a cylinder engraved in a cylinder is:

h=sqrt((4R^2)/3)h=4R23

Cesareo R.
Apr 26, 2017

h = (2sqrt3)/3Rh=233R

Explanation:

Assuming a cylinder with the vertical axis coincident with the zz axis engraved in a sphere centered at the origin and defining

r = R sin thetar=Rsinθ Cylinder base radius
h = 2Rcos thetah=2Rcosθ Cylinder height

we have

V_c = pi r^2 hVc=πr2h Cylinder volume

but

V_c = pi(R sin theta)^2(2R cos theta) = 2pi R^3 sin^2theta cos thetaVc=π(Rsinθ)2(2Rcosθ)=2πR3sin2θcosθ

so

max_(theta) V_c is at theta_0 such that

(d V_c)/(d theta) = 2piR^3(2sin theta cos^2 theta-sin^3 theta)=0

or

{(sin theta = 0),(3cos^2 theta-1 = 0):}

The solutions are

theta = 0 or theta = pm arccos(sqrt3/3)

so

h = (2sqrt3)/3R

NOTE: This is a maximum point because

(d^2V_c)/(d theta^2) = -(8 pi R^3)/sqrt[3] < 0

Frederico Guizini S.
Apr 26, 2017

See the answer below:
This problem has been translated and adapted from the same problem shown in the website http://ecalculo.if.usp.br/derivadas/estudo_var_fun/probl_otimizacao/problemas/problema11.htm

Thanks to the students of Mathematics at USP, University of São Paulo who developed this course in Mathematics as a conclusion paper and posted at http://ecalculo.if.usp.br/.

Explanation:

See the answer below:

This problem has been translated and adapted from the same problem shown in the website http://ecalculo.if.usp.br/derivadas/estudo_var_fun/probl_otimizacao/problemas/problema11.htm

Thanks to the students of Mathematics at USP,University of São Paulo who developed this course in Mathematics as a conclusion paper and posted at http://ecalculo.if.usp.br/.

enter image source here

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