Multivariable Optimization Problem

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Homework Help Overview

The discussion revolves around a multivariable optimization problem involving a parallelepiped with a fixed surface area and the goal of maximizing its volume. The original poster seeks to prove that the optimal shape is a cube.

Discussion Character

  • Exploratory, Conceptual clarification, Mathematical reasoning

Approaches and Questions Raised

  • The original poster attempts to narrow down the proof to a box but expresses confusion about demonstrating that a cube maximizes volume under the given constraints. Another participant introduces the Lagrange multiplier method as a potential approach to find the maximum volume.

Discussion Status

The discussion is ongoing, with some participants exploring the mathematical framework necessary for the proof. Guidance regarding the use of the Lagrange multiplier method has been provided, but no consensus or resolution has been reached yet.

Contextual Notes

There is a distinction being discussed between a box and a parallelepiped, with implications for the problem setup. The original poster indicates that part of the problem may not have been covered in their coursework, suggesting a potential gap in understanding that may affect their ability to engage with the problem fully.

StonedPanda
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I have two questions.

A) Show the parallelipided with fixed surface area and maximum volume is a cube.

I've already proven that we can narrow down the proof to a box. So, basically, I'm really lost on how do prove that a cube is the box with a fixed surface area and maximum volume.

B) We might not have covered how to do part B yet, so i'll create a new topic if I still don't understand after tomorrow's lecture.
 
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How is a "box" different from a parallelpiped?

Call the lengths of the sides of your parallelpiped x, y, and z.

The volume is V= xyz.

The surface area is 2xy+ 2xz+ 2yz= A (a constant).

Now use the "Lagrange multiplier" method.

In order that V= xyz be a minimum (or maximum!) on the surface U=2xy+2xz+ 2yz- A=0, the two gradient vectors, grad V= <yz, xz, xy> and grad U= <2y+ 2z,2x+ 2z, 2x+ 2y> must be parallel. That is we must have <yz, xz, xy>= some multiple of <2y+2z, 2x+ 2z, 2x+ 2y> so that yz= &lambda;(2y+ 2z), xz= &lambda;(2x+ 2z), and
xy= &lambda;<2x+ 2y>. Eliminate &lambda; from tose equations and see what happens.
 
A box is characterized with right angles, whereas a parallellepiped need not be subject to this constraint.
 
Ah, right. Thanks.
 

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