Unbounded Feasible Region for Lagrange with Two Constraints

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Kaura
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Homework Statement



kuGWwwg.jpg


Homework Equations



Partials for main equation equal the respective partials of the constraints with their multipliers

The Attempt at a Solution



UmkCpuX.jpg


Basically I am checking to see if this is correct
I am pretty sure that 25/3 is the minimum but I am not sure how to find the maximum
The max an min at the bottom can be ignored or replaced with minimum
I have a lot to do today to prepare for midterms so any help would be much appreciated
 
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Kaura said:

Homework Statement



kuGWwwg.jpg


Homework Equations



Partials for main equation equal the respective partials of the constraints with their multipliers

The Attempt at a Solution



UmkCpuX.jpg


Basically I am checking to see if this is correct
I am pretty sure that 25/3 is the minimum but I am not sure how to find the maximum
The max an min at the bottom can be ignored or replaced with minimum
I have a lot to do today to prepare for midterms so any help would be much appreciated

Your final solution looks OK, but I did not check the rest because I generally do not look at solutions given as posted images.

You should think about why your solution method does not give you a maximum.
 
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So is 25/3 the only extrema and a minimum?
 
Ray Vickson said:
You tell me. But more importantly, what is the reason?

Yes? because the function is not bound and is continuous?
 
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Kaura said:
Yes? because the function is not bound and is continuous?

Right, and because the feasible region (the set of allowed ##(x,y,z)## values) is unbounded. We can find feasible points ##(x,y,z)## with ##x,z \to -\infty,\: y \to +\infty## (and opposite); and of course, ##f \to +\infty## for such points.