Differential Equation Help

Old_Steve · 2007-05-15 12:06:41

I would appreciate any help on the following:

x+e^ydy-dx=0

I believe it is homogenous but I can't seem to solve it.

Thanks!

Last edited by Old_Steve (2007-05-15 12:47:10)

JaneFairfax · 2007-05-16 03:16:08

Do you mean this differential equation?

(If thats the one, separate the variables and integrate.)

Last edited by JaneFairfax (2007-05-16 03:29:36)

Stanley_Marsh · 2007-05-16 05:22:48

Last edited by Stanley_Marsh (2007-05-16 05:23:03)

Old_Steve · 2007-05-16 06:56:00

It is actually listed in the text as I have entered it. An alternate form may be x + e^y =dx/dy. The answer is x=ce^y+ye^y but I don't know how to get there. I'm going in circles.

Thanks for any help!

JaneFairfax · 2007-05-16 08:18:17

Ah, so it was:

Well,

And now we just solve this second-order differential equation.

It turns out to be

However the original differential equation is a first-order equation, so we must eliminate one of the arbitrary constants. Differentiate:

This must be equal to

for all y. Comparing the coefficients, B = 0.

Hence the solution to the differential equation is

Last edited by JaneFairfax (2007-05-16 08:35:20)

Old_Steve · 2007-05-16 10:47:38

Well...unfortunately you lost me. We have not started second order differential equations yet and I don't think I am supposed to solve it that way. I'll keep trying. Thanks for your help!!!!

JaneFairfax · 2007-05-16 23:16:25

Youre welcome. I actually think second-order equations are much easier to solve than first-order ones. In particular, suppose you have

where a and b are constants. This is called a homogeneous second-order linear ordinary differential equation. To solve it, you consider the auxiliary equation m[sup]2[/sup] + am + b = 0. Suppose the roots are α and β. The general solution is

To solve the inhomogeneous second-order linear ordinary differential equation

(where F is a function of t) look for any function ψ satisfying the above equation, i.e.

ψ is called a particular solution; finding particular solutions is usually quite straightforward (as youll no doubt learn in due course). The general solution to the inhomogeous equation is then the general solution to the homogeous equation plus the particular solution.

Last edited by JaneFairfax (2007-05-16 23:17:35)

George,Y · 2007-05-20 21:51:02

It's the first time I've ever heard that the second order is easier!!

Old_Steve · 2007-05-20 22:07:49

I actually had to go back and work it as a first order equation. It fits the form x' + p(y)x = g(x). I would enter my work but I don't know where you all get your fomula editors. Anyway, I was able to arrive at the correct answer by working it as a firt order equation.

Last edited by Old_Steve (2007-05-20 22:08:10)

JaneFairfax · 2007-05-20 22:39:11

Old_Steve wrote:

It fits the form x' + p(y)x = g(x).

You mean g(y).

Yeah, I just realized how to solve it as a first-order equation as well. You just solve the homogenous case x′ + p(y)x = 0 (which is a variables-separable equation). Then you find a particular solution to x′ + p(y)x = g(y). The general solution to x′ + p(y)x = g(y) is then solution to general case + particular solution.

Is that how you did it?

Old_Steve · 2007-05-21 08:21:57

Yes! It should have been g(y). I was able to solve it as a first order linear diff eq. with u(y)=e^-y. Multiply through and integrate. Then multiply trough again and the answer is x = e^y[y +c].

Last edited by Old_Steve (2007-05-21 13:08:39)

JaneFairfax · 2007-05-21 10:17:43

Hey, that works as well! Great job.

Last edited by JaneFairfax (2007-05-21 10:17:55)

George,Y · 2007-05-21 15:41:19

Yes, Linear!
-1(x)
So e[sup]-y[/sup]|'[sub]y[/sub]=e[sup]-y[/sup](-1)

Math Is Fun Forum

#1 2007-05-15 12:06:41

Differential Equation Help

#2 2007-05-16 03:16:08

Re: Differential Equation Help

#3 2007-05-16 05:22:48

Re: Differential Equation Help

#4 2007-05-16 06:56:00

Re: Differential Equation Help

#5 2007-05-16 08:18:17

Re: Differential Equation Help

#6 2007-05-16 10:47:38

Re: Differential Equation Help

#7 2007-05-16 23:16:25

Re: Differential Equation Help

#8 2007-05-20 21:51:02

Re: Differential Equation Help

#9 2007-05-20 22:07:49

Re: Differential Equation Help

#10 2007-05-20 22:39:11

Re: Differential Equation Help

#11 2007-05-21 08:21:57

Re: Differential Equation Help

#12 2007-05-21 10:17:43

Re: Differential Equation Help

#13 2007-05-21 15:41:19

Re: Differential Equation Help

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