How about this one?,,,y'sinx=yIny

Question

anonymous · Answer

This one is a bit more involved.  It is again separable, so$$\frac{dy}{y.\ln(y)}=\frac{dx}{\sin(x)}$$
The left-hand side can be integrated using the substitution u=ln(y), for then du=(1/y)dy and we can re-write the left-hand side as$$\frac{du}{u} \rightarrow \int\limits_{}{}\frac{du}{u}=\ln(u)+c_1$$Substituting u=ln(y) back in, we get$$\ln(\ln(y))+c_1$$as solution to the left-hand side.
I'll post the right-hand side next...I have to break it up since this site is awkward to use when typing large pieces.

anonymous · Answer

You have to use a t-substitution on the right-hand side.  I was going to go into setting it up, but this site is difficult to use.  I'm going to assume you have heard of the t-substitution (if not, it's easy to find out information).  From this substitution technique, we have two results to use:$$\sin(x)=\frac{2t}{1+t^2}$$ and $$dx=\frac{2dt}{1+t^2}$$Plugging these into dx/sin(x) we have$$\int_{}{}\frac{dx}{\sin(x)} \rightarrow \int\limits_{}{}\frac{1+t^2}{2t}.\frac{2dt}{1+t^2}=\int\limits_{}{}\frac{dt}{t}=\ln(t)+c_2$$Now, from the definition of t-substitution, $$t=\tan(\frac{x}{2})$$so upon substituting, the right-hand side becomes$$\ln(\tan(\frac{x}{2}))+c_2$$

gina · Answer

nice i see)0

gina · Answer

am enjoying  your leasons ,sir

anonymous · Answer

Okay, now we bring the two answers together,$$\ln(\ln(y))+c_1=\ln(\tan(\frac{x}{2}))+c_2$$Collecting the constants on the RHS and exponentiating, we get,$$e^{\ln(\ln(y))}=e^{\ln(\tan(\frac{x}{2}))+(c_2-c_1)}$$Which simplifies to$$\ln(y)=e^{(c_2-c_1)}e^{\ln(\tan(\frac{x}{2}))}=A{\tan(\frac{x}{2})}$$where A is just e^(c_2-c_1), a constant. Exponentiating again isolates y,$$e^{\ln(y)}=e^{Atan(\frac{x}{2})}=e^Ae^{\tan(\frac{x}{2})}=Be^{\tan(\frac{x}{2})}$$where again, B is just the collected constant, e^A. So you're answer is $$y=Be^{\tan(\frac{x}{2})}$$

anonymous · Answer

Grammatical error - *your* answer, not, *you're*.

anonymous · Answer

Remember to check everything.  You can do that by differentiating the final answer - you should be able to get back to the original equation.  I haven't checked anything I've sent, so please do that.

Good luck.  Bed time...

anonymous · Answer

PS - I'm glad you enjoyed the responses!

gina · Answer

wow!!))thanx very much, sir,, i have really enjoyed your responses ,