General Solution of 2y'+y-(2y')*ln(y')=0

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Homework Help Overview

The problem involves finding the general solution of the differential equation 2y' + y - (2y')*ln(y') = 0, which is a first-order ordinary differential equation (ODE) that includes a logarithmic term.

Discussion Character

  • Exploratory, Assumption checking, Mathematical reasoning

Approaches and Questions Raised

  • Participants discuss various methods to handle the logarithmic term, including differentiation and substitution. Some express confusion about the implications of differentiating the equation, while others suggest that a substitution could simplify the problem.

Discussion Status

There is an ongoing exploration of different approaches, including the differentiation of the equation and the introduction of substitutions. Some participants have offered guidance on how to proceed with the integration, while others are questioning the correctness of their manipulations and interpretations of the terms involved.

Contextual Notes

Participants note potential issues with the differentiation process and the assumptions made about the relationships between the variables. There is also mention of time zone differences affecting response times in the discussion.

nothingkwt
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Homework Statement


Find the general solution of 2y' + y - (2y')*ln(y') = 0

Homework Equations




The Attempt at a Solution


I have no idea how to deal with this i mean none of the first order techniques work and it's mainly because I don't know how to deal with the ln(y').

I tried seperating the ln to lndy - lndx but it didn't do any good.
 
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I think a reasonable first step is to differentiate the whole equation once. That should make the logarithm term more approachable.
 
Seemed like a good idea but when I differentiated I feel like I complicated it even more by increasing the order

dy/dx (2y' + y - (2y') * ln(y') = 0)

2y" + y' - 2y" * ln(y') - 2y'*y''/y' = 0
= 2y" + y' - 2y" * ln(y') - 2y''
= y' - 2y" * ln(y')
 
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That's how it may seem, but look closer. It's actually a first order ODE for y', and now the logarithm term makes much more sense. There's an obvious substitution you can make to simplify the equation further.
 
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r = y'
dr = y"

r - 2dr * ln(r) = 0

I feel like something is wrong here maybe I differentiated r incorrectly?
 
nothingkwt said:
Seemed like a good idea but when I differentiated I feel like I complicated it even more by increasing the order

dy/dx (2y' + y - (2y') * ln(y') = 0)

2y" + y' - 2y" * ln(y') - 2y'*y''/y' = 0
= 2y" + y' - 2y" * ln(y') - 2y''
= y' - 2y" * ln(y')

In the first line above, your notation indicates that you are multiplying an equation by dy/dx. What you're actually doing is taking the derivative of each side of an equation.

This notation -- dy/dx(x2) -- means the derivative of some unknown function times x2. Without knowing what dy/dx is, it can't be further simplified.

This notation -- d/dx(x2) means the derivative, with respect to x, of x2, which is 2x.

Your 3rd and 4th lines should be their own equations, with 0 on the right side.
 
Sorry you're right.

2y" + y' - 2y" * ln(y') - 2y'*y''/y' = 0
2y" + y' - 2y" * ln(y') - 2y'' = 0
y' - 2y" * ln(y') = 0
 
nothingkwt said:
r = y'
dr = y"

r - 2dr * ln(r) = 0

I feel like something is wrong here maybe I differentiated r incorrectly?
Yes, instead of dr = y'' you should have dr/dy = y'' or r' = y''.

nothingkwt said:
2y" + y' - 2y" * ln(y') - 2y'*y''/y' = 0
2y" + y' - 2y" * ln(y') - 2y'' = 0
y' - 2y" * ln(y') = 0

Using the tip from clamtrox, if you let u = y', so u' = y''. This will give you a first order DE in u that is separable.
 
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So it would become . . .

r dy - 2 (ln(r)) dr = 0

since r = y'

int ( y'dy) - 2 int (ln(r)) dr) = 0

Is that right?
 
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  • #10
No, that makes no sense. Let's say y is a function of a variable called x. Then y' = dy/dx. This is also a function of x. Now you say r = y'. Also r is a function of x. So your equation is r - 2 dr/dx * ln(r) = 0. Now you can move all r's on one side, and all x's on the other side, and integrate.
 
  • #11
So after integrating r - 2 dr/dx * ln(r) = 0

I get x - 2ln(ln(r)) = 0

x - 2ln(ln(y')) = 0

x = ln(ln(y')^2)

e^x = (ln(y'))^2

I got stuck here not sure how to separate the y.

Sorry about replying so late every time it's cause of the time zone.
 
  • #12
nothingkwt said:
I get x - 2ln(ln(r)) = 0

Something goes wrong here. The integration is very straightforward if you substitute z = ln(r).
 
  • #13
clamtrox said:
Something goes wrong here. The integration is very straightforward if you substitute z = ln(r).

This was after the integration.

r - 2 dr/dx * ln(r) = 0

This is what I integrated.
 

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