How can I approximate $ left(1+frac{2}{4x-1}right)^{x} $

Question

I want to approximate
$$ f(x) = left(1+frac{2}{4x-1}right)^{x} $$
I begin with the Stirling Approximation
$$ n! sim sqrt{2 pi n} left(frac{n}{e}right)^{n}$$
Raise both sides to the power of $$ frac{n+1}{4n(n-1)} = A $$
$$(n!)^{A} sim left(sqrt{2 pi n} left(frac{n}{e}right)^{n}right)^{A} $$
When I plot this on Desmos it looks fine , However if i let :
$$ n = left(1+frac{2}{4x-1}right )$$
To obtain the desired function
$$ left(1+frac{2}{4x-1}right)^{x} $$
on the right side it does not look Asymptotic as $ x to infty $
What can i do , or what function do i use to approximate $ f(x) $  as  $x to infty$
Thank you very much for your help and time.

A learner · Answer

As,
$(1+frac{2}{4x-1})^{x} 
= e^{ln(1+frac{2}{4x-1})^{x}} 
= e^{x ln(1+frac{2}{4x-1})} $.
Now,
$$lim_{x to infty} (1+frac{2}{4x-1})^{x} $$
$$=lim_{x to infty} e^{x ln(1+frac{2}{4x-1})}$$
$$=e^{lim_{x to infty} frac{ln(1+frac{2}{4x-1})}{frac{1}{x}}}$$
$$=e^{lim_{x to infty} frac{frac{-2}{(4x-1)^2} cdot 4 }{(1+frac{2}{4x-1}) cdot frac{-1}{x^2}}} (text{using L'hospital rule}) $$
$$=e^{lim_{x to infty} frac{frac{8}{(4-frac{1}{x})^2}}{(1+frac{2}{4x-1})}} $$
$$=e^{frac{8}{4^2}} $$
$$=sqrt{e} $$

K.defaoite · Answer

Why not use a Taylor expansion? We can use the identity
$$frac{mathrm{d}}{mathrm{d} x}left(f(x)^{g(x)}right)=f(x)^{g(x)}left(g'(x)ln(f(x))+frac{f'(x)}{f(x)}g(x)right)$$
Let $F(x)=left(1+frac{2}{4x-1}right)^x$. Then,
$$F(x)approx F(a)+F'(a)(x-a)+frac{F''(a)(x-a)^2}{2}+O((x-a)^3)$$
In the neighborhood of $x=a$. We can compute using the above identity,
$$F'(x)=F(x)left(lnleft(1+frac{2}{4x-1}right)-frac{8x}{16x^2-1}right)$$
And noting that $frac{mathrm{d}}{mathrm{d}x}left(lnleft(1+frac{2}{4x-1}right)-frac{8x}{16x^2-1}right)=frac{16}{(4x+1)^2(4x-1)^2}$,
$$F''(x)=F'(x)left(lnleft(1+frac{2}{4x-1}right)-frac{8x}{16x^2-1}right)+frac{16cdot F(x)}{(4x+1)^2(4x-1)^2}$$
Expanding around $x=0.4$, e.g:
$$F(x)approx 1.79774810251-1.05158373234(x-0.4)+6.21731638991(x-0.4)^2+O((x-0.4)^3)$$

Axion004 · Answer

Stirling's approximation gives an approximate value for the factorial function $n!$ or the gamma function $Gamma(n)$ when $ngg1$. In your case, there are no factorial functions or gamma functions in $f(x)$ so there is no need to use Stirling's approximation. Instead, take the logarithm:
$$lim_{xtoinfty}log f(x)=lim_{xtoinfty}logleft(1+frac{2}{4x-1}right)^{x}=lim_{xtoinfty}frac{logleft(1+frac{2}{4x-1}right)}{frac{1}{x}},$$
and notice that this limit will approach $0/0$. Therefore we can apply L'Hopital's rule. The derivatives of the numerator and denominator are
$$frac{d}{dx}logleft(1+frac{2}{4x-1}right)=frac{8}{1-16x^2},quadfrac{d}{dx}left(frac{1}{x}right)=frac{-1}{x^2},$$
so the limit may be rewritten as
$$lim_{xtoinfty}frac{8x^2}{16x^2-1}to frac{1}{2}.$$
Can you finish the problem and find $underset{xtoinfty}lim f(x)$?

Dave Robin · Answer

Are you looking for $lim _{x rightarrow infty  }left(1+frac{2}{4x-1}right)^x $?
If so, $$lim _{x rightarrow infty  }left(1+frac{2}{4x-1}right)^x =lim _{x rightarrow  infty  }left(1+frac{1}{frac{4x-1}{2}}right)^{frac{4x-1}{2}cdot frac{2x}{4x-1}}=lim _{x rightarrow  infty  }left(left(1+frac{1}{frac{4x-1}{2}}right)^{frac{4x-1}{2}}right)^{lim _{x rightarrow  infty  } frac{2x}{4x-1}}=e^{frac{1}{2}}=sqrt{e}.$$

How can I approximate $ left(1+frac{2}{4x-1}right)^{x} $

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