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I need to show that a non-degenerate skew symmetric matrix $A$ of even degree is similar to the blockdiagonal matrix $$\begin{pmatrix} D_1 &0&\dots &0\\ 0 &\ddots &0 &\vdots\\ \vdots&0 &\ddots&0\\ 0 &\dots &0&D_n \end{pmatrix} , \text{where } D_i=\begin{pmatrix} 0&-\lambda_i\\ \lambda_i &0\end{pmatrix}.$$

So far, I observed that the matrix $iA$ is hermitian, so it can be diagonalized and further also $A$ can be diagonalized with purely imaginary eigenvalues. By skew symmetry, the eigenvalues come in pairs $\pm i\lambda_i$.
I guess that the $\lambda_i$ in $D_i$ and the diagonalmatrix coincide, as the $D_i$ can be diagonalized by $S=\begin{pmatrix}i&-i\\1&1 \end{pmatrix},$ $D_i=S\begin{pmatrix}-i\lambda_i&0\\0&i \lambda_i \end{pmatrix}S^{-1}$.

It still remains to show that we can find real matrices which do the similarity transformation, i.e. we need to find a real basis in which the bilinearform is of the blockdiagonal form.

I read that this basis is even orthonormal. Why is that?

Edit: I already looked at the similar question Proof of the Wirtinger inequality, where it is stated that one has to " Follow[] the usual linear algebra protocol (taking real and imaginary parts of the complex eigenvectors)". But I have no clue what that means.

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  • $\begingroup$ spectral theorem only gives unitary diagonalization, so how does that differ from what i already know? $\endgroup$ – user506844 Jan 3 '18 at 17:14
  • $\begingroup$ No, I already know, that there is a new orthogonal basis in which the form is diagonal, as it is encoded in the matrix $S$. However, this basis is given by a complex linear combination of the old standard basis vectors. I need to find a real linear combination. Furthermore Orthogonality should still hold for that basis, but thats probably easy to check. $\endgroup$ – user506844 Jan 3 '18 at 17:22
  • $\begingroup$ $A$ isn’t quite arbitrary here. It must be of even degree. $\endgroup$ – amd Jan 3 '18 at 19:04
  • $\begingroup$ @amd I edited my question to include that $\endgroup$ – user506844 Jan 3 '18 at 19:13
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    $\begingroup$ The complex eigenvectors will also come in conjugate pairs. Replace them with the real and imaginary parts of one of the pair. $\endgroup$ – amd Jan 3 '18 at 19:22
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Some comments / remarks towards the solution.

First the statement is not correct. In particular, a skew symmetric matrix can be similar to a matrix $$\begin{pmatrix} D_1 &0&\dots &0 &&&\\ 0 &\ddots &0 &\vdots &&&\\ \vdots&0 &\ddots&0 &&&\\ 0 &\dots &0&D_n\\ &&&&0&&\\ &&&&&\ddots& \\ &&&&&&0 \\ \end{pmatrix}$$

Second You can prove that any real eigenvalue is zero.

Third Consider the case where the dimension of the linear space $\dim E = 2$. Then the minimal polynomial of $A$ is either $\mu_A(X)=X$ or a real polynomial $\mu_A(X)=X^2+bX+a$ with $a \neq 0$. If you suppose that you're in the second case, then you can prove that the matrix of $A$ in any orthonormal basis has the form $$D=\begin{pmatrix} 0&-\lambda\\ \lambda &0\end{pmatrix}.$$

Four To move to the general case, you can consider the minimal polynomial of $A$ which is the product of polynomials of degree $2$ (and potentially the polynomial $X$). For each of those degree 2 polynomials, you have a vector that vanishes it. If not, the minimal polynomial would be of smaller degree. Based on that, you can proceed by induction.

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  • $\begingroup$ Thank you for your answer. I had a nondegenerate bilinearform in mind, so I simply forgot to write down your first and second part. I dont understand the following points though, in particular i am not familiar with what you do with the minimal polynomial. I also don't get the point if what you do in "third": Isn't any skew symmetric 2x2 matrix automatically of the form of $D$? $\endgroup$ – user506844 Jan 3 '18 at 18:43
  • $\begingroup$ Your first point is somewhat belied by your second. For even-degree matrices, you just need to arrange for the zero eigenvalues to come last in the list, and then the block-diagonal matrix is in fact of the form claimed in the OP’s proposition. Then again, that proposition is only true for even-degree skew-symmetric matrices, not “arbitrary” ones as was written. $\endgroup$ – amd Jan 3 '18 at 19:07

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