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I am attempting to solve the linear biharmonic equation in mathematica using DSolve. I think this issue is not just limited to the biharmonic equation but MATHEMATICA just spits out the equation when I attempt to solve it.

I've tried solving other partial differential equations and there was no trouble.

The biharmonic equation is just:

Laplacian^2[f]=0

Here is my equation:

DSolve[
 D[f[x, y], {x, 4}] + 2 D[D[f[x, y], {x, 2}, {y, 2}]] + 
   D[f[x, y], {y, 4}] == 0,
 f,
 {x, y}]

The solution is spit out as

DSolve[(f^(0,4))[x,y]+2 (f^(2,2))[x,y]+(f^(4,0))[x,y]==0,f,{x,y}]

That is obviously not the solution. What gives? What am I missing? I've solved other PDEs without boundary conditions.

share|improve this question
    
According to the documentation of DSolve, the function can "solve many linear equations up to second order with nonconstant coefficients". So my guess is that DSolve fails because the biharmonic equation is a fourth order PDE. –  Heike Oct 18 '11 at 16:15
    
@Heike Looks to be the case. How am I to solve this equation in mathematica? I have solved fourth order non-linear pdes before, but with NDSolve... –  drN Oct 18 '11 at 16:23
1  
1  
Shouldn't your second term be D[f[x, y], {x, 2}, {y, 2}] or D[D[f[x, y], {x, 2}], {y, 2}]? –  Meng Lu Oct 18 '11 at 16:59
1  

1 Answer 1

up vote 6 down vote accepted

How about try it in polar coordinates? If f(r, \[Theta]) is symmetric with respect to azimuth \[Theta], the biharmonic equation reduces to something Mathematca can solve symbolically (c.f. http://mathworld.wolfram.com/BiharmonicEquation.html):

In[22]:= eq = D[r D[D[r D[f[r],r],r]/r,r],r]/r;
eq//FullSimplify//TraditionalForm

Out[23]//TraditionalForm= f^(4)(r) + (2 r^2 f^(3)(r) - r f''(r)
                           + f'(r))/r^3

In[24]:= DSolve[eq==0,f,r]
Out[24]= {{f -> Function[{r}, 
                 1/2 r^2 C[2] - 1/4 r^2 C[3] + C[4] + C[1] Log[r] 
                   + 1/2 r^2 C[3] Log[r]
                ]}}

In[25]:= ReplaceAll[
    1/2 r^2 C[2]-1/4 r^2 C[3]+C[4]+C[1] Log[r]+1/2 r^2 C[3] Log[r],
    r->Sqrt[x^2+y^2]
]
Out[25]= 1/2 (x^2+y^2) C[2]-1/4 (x^2+y^2) C[3]+C[4]+C[1] Log[Sqrt[x^2+y^2]]+ 
1/2 (x^2+y^2) C[3] Log[Sqrt[x^2+y^2]]
share|improve this answer
    
This helps a lot! Thanks! :) however, I'd love to be able to do it in cartesian coordinates. –  drN Oct 19 '11 at 17:39

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