# Solving the biharmonic equation in mathematica

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.

-
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
– Dr. belisarius Oct 18 '11 at 16:48
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
– Dr. belisarius Oct 18 '11 at 16:59

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;

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]]
``````
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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