standard limit indication

[Vali]

Hi!
I have the limit from the below picture.
I have to use that formula but I don't know how.
I need to split that limit in 2 limits then the result should give n^2 + n^2 (from that standard limit) and the result will be sqrt(2)^2 + sqrt(2)^2 = 4
Thanks!

 

[Steven G]

Hi!
I have the limit from the below picture.
I have to use that formula but I don't know how.
I need to split that limit in 2 limits then the result should give n^2 + n^2 (from that standard limit) and the result will be sqrt(2)^2 + sqrt(2)^2 = 4
Thanks!

What formula? You need to understand better what an equal sign means. One of its meaning is that you can replace what is on one side of the equal sign with what is on the other side of the equal sign, You are being asked to replace x with 1/t and sqrt(2) with n. Can you please do that and see if you can go further? Then report back to us showing your work so we can assist you further.

 

[Vali]

How to continue ?
If I add subtract 1 at numerator I can use that standard limit but I don't get the right answer.

 

[Steven G]

View attachment 10816 How to continue ?
If I add subtract 1 at numerator I can use that standard limit but I don't get the right answer.

Please show us what you did get so we see where/if you made any errors.

 

[pka]

Hi!
I have the limit from the below picture.
I have to use that formula but I don't know how.
I need to split that limit in 2 limits then the result should give n^2 + n^2 (from that standard limit) and the result will be sqrt(2)^2 + sqrt(2)^2 = 4

I was able to do this after understanding your notation.
\(\displaystyle \mathop{\lim }\limits_{x \to \infty } \left[ {\dfrac{{{{(x + \sqrt 2)}^{\sqrt 2 }} - {{(x - \sqrt 2 )}^{\sqrt 2 }}}}{{{x^{\sqrt 2 -1}}}}} \right] = \mathop {\lim }\limits_{x \to \infty } \left\{{\dfrac{{{{\left( {1 + \dfrac{{\sqrt 2 }}{x}} \right)}^{\sqrt 2 }} -{{\left( {1 - \dfrac{{\sqrt 2 }}{x}} \right)}^{\sqrt 2 }}}}{{{x^{ -1}}}}} \right\}\)

If \(\displaystyle t=x^{-1}\) then \(\displaystyle \mathop {\lim }\limits_{x \to \infty } \left\{ {\frac{{{{\left( {1 + \dfrac{{\sqrt 2 }}{x}} \right)}^{\sqrt 2 }} - {{\left( {1 - \dfrac{{\sqrt 2 }}{x}} \right)}^{\sqrt 2 }}}}{{{x^{ - 1}}}}} \right\} = \mathop {\lim }\limits_{t \to 0} \left\{ {\dfrac{{{{\left( {1 + \sqrt 2 t} \right)}^{\sqrt 2 }} - {{\left( {1 - \sqrt 2 t} \right)}^{\sqrt 2 }}}}{t}} \right\}\) Now we have \(\displaystyle \dfrac{0}{0}\)

Using l'Hopital's theorem: \(\displaystyle \mathop {\lim }\limits_{t \to 0} \left\{ {\dfrac{{{{\left( {1 + \sqrt 2 t} \right)}^{\sqrt 2 }} - {{\left( {1 - \sqrt 2 t} \right)}^{\sqrt 2 }}}}{t}} \right\}\overbrace {\; = \;}^H\mathop {\lim }\limits_{t \to 0} \left\{ {\dfrac{{\sqrt 2 {{\left( {1 + \sqrt 2 t} \right)}^{\sqrt 2 - 1}}\left( {\sqrt 2 } \right) - \sqrt 2 {{\left( {1 - \sqrt 2 t} \right)}^{\sqrt 2 - 1}}\left( { - \sqrt 2 } \right)}}{1}} \right\} \to 4\)

 

[Vali]

Thanks a lot!