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I haven't used my algebra skills much for years and they seem to have atrophied significantly!

I'm having real trouble working out how to re-arrange a formula I've come across to get $x$ by itself on the left hand side. It looks like this:

$\frac{x}{\sqrt{A^{2}-x^{2}}}=\frac{B+\sqrt{C+Dx}}{E+\sqrt{F+G\sqrt{A^{2}-x^{2}}}}$

I've tried every method I can remember but I can't get rid of those pesky square roots!

Any ideas?

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    Is it not just a question of squaring on both sides?2011-03-12
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    @utdiscant: Not "just" that; that will still leave a radical and a nested radical on the right hand side. You can probably go from there, though.2011-03-12
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    There are so many square roots that I wind up with as many after squaring (due to cross terms) as there were before.2011-03-12
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    I've had Mathematica churning away at isolating $x$ for a few minutes now—since Mathematica didn't isolate the variable in a few seconds, I'm guessing that isolating it is not at all simple.2011-03-13

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I would start by multiplying the numerator and denomenator on the right by $E-\sqrt{F+G\sqrt{A^2-x^2}}$: $$\frac{x}{\sqrt{A^2 - x^2}} = \frac{\left(B + \sqrt{C + Dx}\right)\left(E - \sqrt{F + G\sqrt{A^2 - x^2}}\right)}{E^2-F+G\sqrt{A^2 - x^2}}$$

It may also help the manipulation to set $y = \sqrt{A^2 - x^2}$ for a while.

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    @F.P.Adams: Note that the LHS side with that substitution becomes: $\frac{x^2}{y^2}$2011-03-13
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    "squaring the left side" sounds like an abusive way to treat an equality2011-03-13
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    derp yeah sorry2011-03-13