First order linear partial differential equation

coverband
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Do these equations have two general solutions!?

e.g. z_x + z_y -z = 0

Using the method of characteristics

a=1
b=1
c=-1
d=0

Therefore dx/1=dy/1=dz/z

Taking first two terms: x = y + A
*Taking last two terms: z = Be^y
So general solution is z = f(x-y)e^y

BUT if we took first and last terms: z=Be^x
z=f(x-y)e^x...
 
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Neither of those is the "general" solution. z= f(x-y)ex+ g(x-y)ey is the general solution.
 
You are quite the genius! Thanks
 
HallsofIvy said:
Neither of those is the "general" solution. z= f(x-y)ex+ g(x-y)ey is the general solution.

I disagree - first order PDE's don't have two arbitrary functions in their solutions!

coverband said:
Do these equations have two general solutions!?

e.g. z_x + z_y -z = 0

Using the method of characteristics

a=1
b=1
c=-1
d=0

Therefore dx/1=dy/1=dz/z

Taking first two terms: x = y + A
*Taking last two terms: z = Be^y
So general solution is z = f(x-y)e^y

BUT if we took first and last terms: z=Be^x
z=f(x-y)e^x...
Actually, they're both right.

First solution z = e^xf(x-y) second solution z = e^y g(x-y). Since f is arbitrary the set f(x-y) = e^{-(x-y)} g(x-y) and the first becomes the second.
 
What, you mean I'm NOT a genius?
 
HallsofIvy said:
What, you mean I'm NOT a genius?
I've never met you so I really don't know :smile:
 

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