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It's been quite a while since I last dealed with DE's. I'd appreciate if you could help me with the official, or usual, classification of the next DE's and/or if there are some definite methods to solve them. Hints will also be welcome:

$$(1)\;\;\;\;\;\;\;\;y'=\frac{(y+2x-1)^2}{(4y+8x-6)(2y+4x-1)}\cdot\frac{1}{\sin\left(\frac{4y+8x-3}{y+2x-1}\right)}-2$$

$$(2)\;\;\;\;\;\;\;\;y'x+y\left(\ln^2x+\ln^2y-2\ln x\ln y\right)=0\;\;,\;x,y>0$$

I'm guessing here one could write

$$\ln^2x+\ln^2y-2\ln x\ln y=\left(\ln x-\ln y\right)^2=\ln^2\frac{x}{y}$$

Thanks.

  • 2
    Are you sure you copied (1) correctly? Apart from the $4x+8y-6$, the right side depends only on $y+2x$. If you changed $4x+8y-6$ to $4y+8x-6$, things would be much simpler.2012-11-29
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    Of course, you're right!2012-11-29
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    I am fond of ODEs. Nice Don. I didn't know you posted a question in this area. +2013-03-11

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That guess is a good one. Further hint: $y'$ depends only on $y/x$.

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    Thanks, I see your point: $$y'=-\frac{y}{x}\,\log^2\frac{y}{x}$$ Putting now $$z=\frac{y}{x}\Longrightarrow \frac{dy}{dx}=z+x\frac{dz}{dx}$$ so the eq. becomes $$z+x\frac{dz}{dx}=-z\log^2z\Longrightarrow-\frac{dz}{z(\log^2z+1)}=\frac{dx}{x}\Longrightarrow$$ $$-\arctan\log z=\log x+C\Longrightarrow\log z=\tan(-\log z)=\tan\log x+C'$$ I wonder whether this is enough...2012-11-29