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I have a problem with the DSolve[] command in mathematica 8. Solving the the following 4th order differential equation spits out a complex solution although it should be a real one. The equation is:

y''''[x] + a y[x] == 0

Solving this equation by hand yields a solution with only real parts. All constants and boundary conditions are also real numbers.

The solution I get by hand is:

y1[x_] = (C[5] E^(Power[a, (4)^-1]/Power[2, (2)^-1] x) + 
  C[6] E^(-(Power[a, (4)^-1]/Power[2, (2)^-1]) x)) Cos[
 Power[a, (4)^-1]/Power[2, (2)^-1]
   x] + (C[7] E^(Power[a, (4)^-1]/Power[2, (2)^-1] x) + 
  C[8] E^(-(Power[a, (4)^-1]/Power[2, (2)^-1]) x)) Sin[
 Power[a, (4)^-1]/Power[2, (2)^-1] x];

Now I have to solve for the constants C[5]...C[8]. This arises a similar issue. I use the Solve[] command with the boundary conditions

Solve[{y1''[-c] == ic0, y1''[c] == ic0 , y1'''[-c] == ic1 , 
y1'''[c] == - ic1 }, {C[5], C[6], C[7], C[8]} ];

The constants C[5]...C[8] are now real if using //Simplify and complex if using //FullSimplify.

Any idea what the reasons are? The notebook with my calculations can be downloaded under:

In further work I have to use DSolve[] and I would like to understand the issue here.



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closed as off topic by Tim Post Sep 5 '12 at 14:17

Questions on Stack Overflow are expected to relate to programming within the scope defined by the community. Consider editing the question or leaving comments for improvement if you believe the question can be reworded to fit within the scope. Read more about reopening questions here.If this question can be reworded to fit the rules in the help center, please edit the question.

I think that some of your statements depend on the details. For instance some of the parameters C[] can be complex numbers if you choose a<0 :

parS = Solve[{y1''[-c] == ic0, y1''[c] == ic0, y1'''[-c] == ic1, 
    y1'''[c] == -ic1}, {C[5], C[6], C[7], C[8]}] // Simplify;
parFS = Solve[{y1''[-c] == ic0, y1''[c] == ic0, y1'''[-c] == ic1, 
    y1'''[c] == -ic1}, {C[5], C[6], C[7], C[8]}] // FullSimplify

parS /. {a -> -2, c -> 10, ic0 -> 1, ic1 -> -1} // N
parFS /. {a -> -2, c -> 10, ic0 -> 1, ic1 -> -1} // N

(* {{C[5] -> -0.35876 - 2.498*10^-15 I,  C[6] -> -0.35876 - 2.498*10^-15 I, 
     C[7] -> 2.27596*10^-15 - 0.358762 I, C[8] -> -2.27596*10^-15 + 0.358762 I}}

   {{C[5] -> -0.35876 + 5.10703*10^-15 I, C[6] -> -0.35876 + 5.10703*10^-15 I, 
     C[7] -> 2.35922*10^-15 - 0.358762 I, C[8] -> -2.19269*10^-15 + 0.358762 I}} *)

Besides this point you can get the solution to your problem in one line and indeed it seems a real function (apart from numerics) :

sol[a_, ic0_, ic1_, c_, x_] = y[x] /. DSolve[{y''''[x] + a y[x] == 0, y''[-c] == ic0, 
     y''[c] == ic0, y'''[-c] == ic1, y'''[c] == -ic1}, y[x], x][[1]] ;

Plot[Im[sol[-2.0, 1.0, -1.0, 10., x]], {x, -10., 10.}]
Plot[Re[sol[-2.0, 1.0, -1.0, 10., x]], {x, -10., 10.}]

Im Re

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Hi,Thanks for your answer. I forgot to give the download link for my notebook. it can be downloaded under: I also get this behaviour in the symbolic calculation (in the notebook y3[x] is Real and y4[x] is complex). Also for a>0 I get complex constants – user1622055 Sep 4 '12 at 10:13

Since you cross-posted the question to Mathematica.SE, I gave an answer there. The crux of it is that even with a real and positive value for a, the general solution to your fourth-order differential equation is complex. Period. If you happen to be only interested in the real solutions, it is possible to extract them.

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