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Is it possible to get the value of $y$ in terms of $x$ from the below equation? If so please give give me a clue how to do that :) $y \sqrt{y^2 + 1} + \ln\left(y + \sqrt{y^2 + 1}\right) = \frac{a}{x^2}.$

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    Unfortunately, it is a multiplication. Can you tell me please how to start with it?2012-08-28

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Since $\ \rm{asinh}(y)=\ln\left(y + \sqrt{y^2 + 1}\right)\ $ let's set $\ y:=\sinh(u)\ $ and rewrite your equation as :

$\sinh(u) \sqrt{\sinh(u)^2 + 1} + u = \frac{a}{x^2}$ $\sinh(u) \cosh(u) + u = \frac{a}{x^2}$ $\sinh(2u) + 2u = 2\frac{a}{x^2}$

After that I fear you'll have to solve this numerically (to get $u$ in function of $x$).

I don't see something simpler sorry...


To solve $\ \sinh(w) + w = r\ $ numerically you may :

  • use iterations (Newton-Raphson) : $\ \displaystyle w_{n+1}=w_n-\frac {\sinh(w_n)+w_n-r}{\cosh(w_n)+1}$
    (starting with $w_0=\frac r2$)
  • use reversion of series to get $w=w(r)$ : $w(r)= \frac 12 r - \frac 1{96}r^3 + \frac 1{1920}r^5 - \frac{43}{1290240}r^7 + \frac {223}{92897280}r^9 - \frac{60623}{326998425600}r^{11} + \frac{764783}{51011754393600}r^{13} - \frac {107351407}{85699747381248000}r^{15} + \mathrm{O}\bigl(r^{17}\bigr)$
  • perhaps that other methods exist in the litterature...
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    @user1354439: +1 to begin your generous work (not for me, I don't really need it!).2012-08-28