How would you find the maximal value of $f(x,y) = x - y^2$ on $K = \left\{ (x,y) : \frac{x^2}{4} + \frac{y^2}{9} = 1 \right\}$?
Finding the maximal value of a function on a ellipse
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0I like your first solution better. A little alertness and common sense pays off sometimes. – 2012-06-08
2 Answers
Because $\frac{x^2}4 + \frac{y^2}9 = 1$, we know $y^2 = 9\left(1 - \frac{x^2}4\right)$. Substitute this into $x-y^2$ should give a function depending on $x$ only, which you can easily find the maximum (and remember that $x\in[-2,2]$).
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0@Gigili: Because otherwise there is no real solution to $\frac{x^2}4+\frac{y^2}9=1$. – 2012-06-08
Use the constraint $(9/4)x^2 - 9 = -y^2$ and plug in to $f(x,y)$. You will get
$f(x) = x + (9/4)x^2 - 9$.
Differentiate, $f'(x) = 1 + (9/2)x$,
solve $ 2 + 9x = 0$ and get $ x = -\frac{2}{9}$.
Now you must perform a "sanity check" to see if $x$ is in $K$. Since $x \in \pi_xK$ iff $x^2 \le 4$, ifff $ -2 \le x \le 2$, we see that $x=-(2/9)$ satisfy the condition and thus $(x,\mbox{the matching }y) \in K$.
Now, to see if it's a maximum or a minimum, differentiate again:
$f''(x) = 9/2 > 0$ so it is a minimum. Since $f(x)$ is continuous in a closed interval $[-2,2]$ (and in no other place the derivative is 0) it gets its maximum on one of the end points. Now, plug in $x = \pm 2$ in $f(x)$ and find which gives the bigger value of $f(x)$.