I'm assuming you want to solve something like

```
u1''[x] + 10 u1[x] == mu1 u1[x]
```

with boundary conditions

```
u1[x0] == 0; u1[x1] == 0; u1'[x0] =!= 0
```

for some `x0 < x1`

. One way to do that is to first solve the differential equation plus the boundary conditions at `x0`

, e.g.

```
sol = DSolve[{mu1 u1[x] - u1''[x] - 10 u1[x] == 0, u1[x0] == 0, u1'[x0] == 1}, u1, x][[1]]
```

which gives as output

```
{u1 -> Function[{x}, -((E^(-Sqrt[-10 + mu1] x - Sqrt[-10 + mu1] x0)
(-E^(2 Sqrt[-10 + mu1] x) + E^(2 Sqrt[-10 + mu1] x0)))/(2 Sqrt[-10 + mu1]))]}
```

We can then use this solution to find `mu1`

such that the boundary condition at `x1`

is satisfied:

```
sol1 = Solve[{u1[x1] == 0 /. sol[[1]], x1 > x0}, mu1, MaxExtraConditions -> All]
```

From which we find

```
{{mu1 -> ConditionalExpression[(10 x0^2 - 20 x0 x1 + 10 x1^2 - 4 \[Pi]^2 C[1]^2)/(
x0^2 - 2 x0 x1 + x1^2),
x0 \[Element] Reals && C[1] \[Element] Integers && C[1] >= 1 && x1 > x0]},
{mu1 -> ConditionalExpression[(-\[Pi]^2 + 10 x0^2 - 20 x0 x1 + 10 x1^2 -
4 \[Pi]^2 C[1] - 4 \[Pi]^2 C[1]^2)/(x0^2 - 2 x0 x1 + x1^2),
x0 \[Element] Reals && C[1] \[Element] Integers && C[1] >= 0 && x1 > x0]}}
```

`mu1`

like`u1[x_]:= Ct E^(+/-)(Sqrt[-10 + mu1] x)`

– Dr. belisarius Jun 9 '12 at 6:51notexactly the same thing you are looking for. Also see Eigenvalues and vectors. – chessofnerd Jun 9 '12 at 16:29