Problem with $A.M.geq G.M.$ Inequality

Question

Question:

If $x^2+y^2=1$, prove that $-{sqrt2}leq x+y leqsqrt2$

My approach:
$$frac{x^2+y^2}{2}geqsqrt{x^2y^2}$$
$$ frac12geq xy$$
$$frac{-1}{sqrt2}leqsqrt{xy}leq frac{1}{sqrt2} $$
Now how do I proceed from here?

Anand · Answer

Use $T_2$'s lemma to get,
$$1=x^2+y^2geq frac{(x+y)^2}{2}$$

nguyenhuyenag · Answer

Using the Cauchy-Schwarz inequality we have
$$(x+y)^2 leqslant (1+1)(x^2+y^2) = 2(x^2+y^2) = 2.$$
So $$|x+y| leqslant sqrt{2},$$ or $$ -sqrt 2  leqslant x + y leqslant sqrt 2.$$

SarGe · Answer

$$x^2+y^2=1\(x+y) ^2=1+2xytag{1}$$ Now, you've got that $$frac{1}{2}ge xy\ frac{1}{2}ge frac{(x+y) ^2-1}{2}tag{from (1)}\ (x+y) ^2le 2\ -sqrt 2le x+yle sqrt 2$$

enzotib · Answer

Another way: set $x=costheta, y = sintheta,$ then
$$
x+y=costheta+sintheta=sqrt{2}cos(theta-pi/4)
$$

Nikunj · Answer

Proceeding from your approach, you had
$$2xy leq 1$$
Adding $x^2 + y^2$ to both sides,
$$implies x^2+2xy+y^2 leq 1 + x^2 + y^2$$
$$implies (x+y)^2 leq 1 + 1$$
And you're done.

lab bhattacharjee · Answer

Using  Brahmagupta-Fibonacci Identity or directly
$$(x+y)^2+(x-y)^2=(1^2+1^2)(x^2+y^2)$$
$$2(x^2+y^2)-(x+y)^2=cdotsge0$$

Problem with $A.M.geq G.M.$ Inequality

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