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I am trying to help my daughter on her math homework and I am having some trouble on some equation solving steps. My current major concern relies on understanding why $\sqrt{8}/2$ equal to $\sqrt{2}$.

Thanks in advance

  • 16
    It isn’t: $\frac{\sqrt8}2=\sqrt2\ne 2=\sqrt4$.2012-11-12
  • 3
    @BrianM.Scott: But [$\sqrt2=2$](http://math.stackexchange.com/questions/229263/two-paradoxes-pi-2-and-sqrt-2-2)! :-)2012-11-12
  • 1
    Yes, has you all have noted, I made a mistake. Instead of writing sqrt(2), I wrote sqrt(4), which of course is 2. I have already fixed my question. Reading your answers I have already understood the solution. Thanks a lot for that!2012-11-12
  • 3
    To clarify what the edit to the question was: the question [originally asked](http://math.stackexchange.com/revisions/235998/3), incorrectly, why $\sqrt{8}/2$ is equal to $\sqrt{4}$. Now it correctly asks why $\sqrt{8}/2$ is equal to $\sqrt{2}$.2012-11-13
  • 0
    [Related](http://math.stackexchange.com/q/535634/28900).2013-10-22

8 Answers 8

7

Other techniques to prove that result:


Technique $\mathbf 1$:

We may also prove that by solving this equation for $x$:

$$\begin{align}\frac{\sqrt x}{2}&=\sqrt2\\\sqrt x&=2\sqrt 2\\\left(\sqrt x\right)^2&=\left(2\sqrt 2\right)^2\\x&=4\cdot2=\color{green}{\boxed{\color{black}{8}}}\end{align}$$

Therefore: $$\frac{\sqrt8}{2}=\sqrt 2$$ I know, this is a terrible way. But hey, it works! ;-)


Technique $\mathbf 2$:

Just like in Technique $\mathbf 1$: We may also prove that result by solving this equation for $x$:

$$\begin{align}\frac{\sqrt 8}{2}&=\sqrt x\\ \left(\frac{\sqrt 8}{2}\right)^2&=\sqrt x^2\\ \frac84&=x \implies x=\color{green}{\boxed{\color{black}2}} \end{align}$$

Therefore: $$\frac{\sqrt8}{2}=\sqrt 2$$


Technique $\mathbf 3$:

If $a=b$ then this means $a-b=0$, and the opposite is true. So let's check for $\sqrt 2$ and $\sqrt 8/2$:$$\begin{align}\dfrac{\sqrt 8}{2}-\sqrt{2}&=\dfrac{\sqrt 8}{2}-\left(\sqrt{2} \cdot \dfrac{\sqrt{4}}{2}\right)\quad\to\quad\text{since $\sqrt 4=2$}\\ &=\dfrac{\sqrt 8}{2}-\dfrac{\sqrt 2\cdot\sqrt 4}{2}\\ &=\dfrac{\sqrt{8}-\sqrt{2}\cdot\sqrt{4}}{2}\\ &=\dfrac{\sqrt{8}-\sqrt{2\cdot4}}{2}\\ &=\dfrac{\sqrt 8-\sqrt 8}{2}=\dfrac{0}{2}=0 \end{align}$$ Therefore, we can easily conclude that: $$\dfrac{\sqrt 8}{2}=\sqrt 2$$


Technique $\mathbf 4$:

If $a=b$ then it follows that $a/b=1$, and the opposite is true. So let's check for $\sqrt 2$ and $\sqrt 8/2$: $$\begin{align}\dfrac{\sqrt2}{\dfrac{\sqrt8}{2}}&=\sqrt{2}\cdot\dfrac{2}{\sqrt{8}}=\dfrac{\sqrt2\cdot\sqrt 4}{\sqrt8}=\dfrac{\sqrt{2\cdot 4}}{\sqrt 8}=\dfrac{\sqrt8}{\sqrt8}=1 \end{align}$$ Therefore: $$\dfrac{\sqrt 8}{2}=\sqrt 2$$


Technique $\mathbf 5$:

We will do a proof by contradiction: We suppose that $\sqrt 8/2\ne\sqrt 2$, therefore there must be a difference between them which is not zero $\sqrt 8/2-\sqrt 2\ne0$, that we will call $x$. So let's check if $x\ne0$: $$\begin{align}x=\dfrac{\sqrt 8}{2}-\sqrt{2}&=\dfrac{\sqrt 8}{2}-\left(\sqrt{2} \cdot \dfrac{\sqrt{4}}{2}\right)\\ &=\dfrac{\sqrt 8}{2}-\dfrac{\sqrt 2\cdot\sqrt 4}{2}\\ &=\dfrac{\sqrt{8}-\sqrt{2}\cdot\sqrt{4}}{2}\\ &=\dfrac{\sqrt{8}-\sqrt{2\cdot4}}{2}\\ &=\dfrac{\sqrt 8-\sqrt 8}{2}=\dfrac{0}{2}=0 \end{align}$$But this is a contradiction, since $x$ must be non-zero but it turns out that it is equal to $0$. Therefore: $$\dfrac{\sqrt 8}{2}=\sqrt 2$$


Generalization: Let $x$ be a strictly positive number in $\Bbb R$, then: $$\dfrac{\sqrt{x^3}}{x}=\sqrt{x}$$

Proof: $$\dfrac{\sqrt{x^3}}{x}=\dfrac{\sqrt{x^3}}{\sqrt{x^2}}=\sqrt{\dfrac{x^3}{x^2}}=\sqrt x\qquad\blacksquare\\\,\\\textit{inspired by Paul Dirac's post :)}$$

55

I am a bit surprised that nobody suggested $$\left({\frac{\sqrt 8}2}\right)^2 = \frac{{\left(\sqrt 8\right)}^2}{2^2} = \frac84 = 2. $$

  • 3
    This is certainly what I would have said.2012-11-13
  • 0
    Sorry, but this answser is certainly wrong.2012-11-13
  • 15
    @JulioNobre: no, it isn't.2012-11-13
  • 12
    @julio The definition of $\sqrt2$ is that it is the unique positive number whose square is 2. $\frac{\sqrt8}2$ is a positive number, and I've demonstrated that its square is 2.2012-11-13
  • 1
    Ok. Now I got it :D2012-11-13
  • 0
    For what it's worth, I think it would have helped however slightly and been minimal trouble to just spell it out in the first place and make explicit that $\sqrt{8}/2$ is positive (since the question could well have been about $- \sqrt{8}/2$ instead in which case the calculation by itself is misleading).2015-11-28
  • 0
    In proving the sum of two continuous functions is itself continuous, I sometimes see 'Suppose $\varepsilon > 0$. Noting that $\varepsilon / 2 > 0$, $\dots$', and on an exam question of a similar flavor, a student once unwittingly let it be negative and 'proved' vacuous garbage, so such an indication is not at all superfluous.2015-11-28
53

It isn't, as originally written. To see why the fixed version is correct, we have:

$$\frac{\sqrt{8}}2=\frac{\sqrt{4\cdot2}}2=\frac{\sqrt{4}\sqrt{2}}2=\frac{2\sqrt{2}}2=\sqrt{2}.$$

  • 1
    Altough Samuel Reid's was also insighfull, I think your explanation was more acessible to me. That is is why I will mark it as right answer. Thanks for both of you!2012-11-12
26

It’s simple:

$$\frac{\sqrt{8}}{2} = \frac{\sqrt{2 \cdot 2 \cdot 2}}{\sqrt{2 \cdot 2}} = \sqrt{2}$$

:)

  • 2
    Yes, I loved its simplicity :D2012-11-13
21

$$\frac{\sqrt8}{2}=\frac{\sqrt8}{\sqrt{2^2}}=\sqrt{\frac{8}{2^2}}=\sqrt{\frac{8}{4}}=\sqrt2.$$

20

By noting that $2^3 =8$, you have $$\frac{\sqrt{8}}{2} = \frac{\sqrt{2^3}}{2} = \frac{ 2^{3/2}}{2} = 2^{1/2}=\sqrt{2} \neq \sqrt{4}$$

18

Geometric approach:

enter image description here

Now what is $\displaystyle\text{AB}/2$ ?

  • 2
    I've loved your aproach. Thanks!2013-12-01
  • 0
    You're welcome @JulioNobre ! :-)2013-12-20
  • 2
    I really love the post full of graphs. +12013-12-27