# Free boundary conditions in MATHEMATICA - is this right? Second opinion

I'm trying to prescribe free boundary conditions for a non-linear evolution equation in mathematica and I wanted as second opinion on whether or not what I am doing is right.

The boundary conditions have been marked with a comment, viz., (FREE BOUNDARY CONDITIONS)

I'd also like to run this for pinned boundary conditions.

``````Needs["VectorAnalysis`"]
Needs["DifferentialEquations`InterpolatingFunctionAnatomy`"];
Clear[Eq5, Complete, h, S, G, E1, K1, D1, VR, M]
Eq5[h_, {S_, G_, E1_, K1_, D1_, VR_, M_}] := \!\(
\*SubscriptBox[\(\[PartialD]\), \(t\)]h\) +
Div[-h^3 G Grad[h] +
h^3 S Grad[Laplacian[h]] + (VR E1^2 h^3)/(D1 (h + K1)^3)
Grad[h] + M (h/(1 + h))^2 Grad[h]] + E1/(h + K1) == 0;
SetCoordinates[Cartesian[x, y, z]];
Complete[S_, G_, E1_, K1_, D1_, VR_, M_] :=
Eq5[h[x, y, t], {S, G, E1, K1, D1, VR, M}];
TraditionalForm[Complete[S, G, E1, K1, D1, VR, M]]

L = 185.62; TMax = 100; km = 0.0381;
Off[NDSolve::mxsst];
Off[NDSolve::ibcinc];
hSol = h /. NDSolve[{Complete[100, 0, 0, 0, 0.001, 0, 5],

(*FREE BOUNDARY CONDITIONS*)

Derivative[2, 0, 0][h][0, y, t] == 0,
Derivative[2, 0, 0][h][L, y, t] == 0,
Derivative[0, 2, 0][h][x, 0, t] == 0,
Derivative[0, 2, 0][h][x, L, t] == 0,
Derivative[3, 0, 0][h][0, y, t] == 0,
Derivative[3, 0, 0][h][L, y, t] == 0,
Derivative[0, 3, 0][h][x, 0, t] == 0,
Derivative[0, 3, 0][h][x, L, t] == 0,

(*FREE BOUNDARY CONDITIONS*)

h[x, y, 0] == 1 + (-0.05*Cos[2*Pi*(x/L)] - 0.05*Sin[2*Pi*(x/L)])*
Cos[2*Pi*(y/L)]},
h, {x, 0, L}, {y, 0, L}, {t, 0, TMax}][[1]]
hGrid = InterpolatingFunction[hSol];
{TMin, TRup} = InterpolatingFunctionDomain[hSol][[3]]
``````
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I'm guessing that `hsol` on the penultimate line of your code should have been `hSol` (with a capital S). Since `hSol` is already an `InterplatingFunction` the definition of `hGrid` doesn't really make sense. –  Heike Jan 11 '12 at 15:36
@Heike Thanks for pointing that out. Other than that, what do you think of the implementation of free boundary conditions (The second and third derivatives of the 'edges' are set to zero)? –  drN Jan 11 '12 at 15:40
The implementation of the boundary conditions seems ok. –  Heike Jan 11 '12 at 15:49
@Heike I was thinking so too from my bending moment days. But I just had to check anyway! Thanks! :) –  drN Jan 11 '12 at 19:08
@Heike, why don't you just post your comment as an answer. –  user1054186 Jan 12 '12 at 10:34