Skew-Hermitian matrix

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In linear algebra, a square matrix with complex entries is said to be skew-Hermitian or anti-Hermitian if its conjugate transpose is the negative of the original matrix.^[1] That is, the matrix ${\displaystyle A}$ is skew-Hermitian if it satisfies the relation

where ${\displaystyle A^{\mathsf{\text{𝖧}}}}$ denotes the conjugate transpose of the matrix ${\displaystyle A}$. In component form, this means that

for all indices ${\displaystyle i}$ and ${\displaystyle j}$, where ${\displaystyle a_{ij}}$ is the element in the ${\displaystyle i}$-th row and ${\displaystyle j}$-th column of ${\displaystyle A}$, and the overline denotes complex conjugation.

Skew-Hermitian matrices can be understood as the complex versions of real skew-symmetric matrices, or as the matrix analogue of the purely imaginary numbers.^[2] The set of all skew-Hermitian ${\displaystyle n\times n}$ matrices forms the ${\displaystyle u(n)}$ Lie algebra, which corresponds to the Lie group U(n). The concept can be generalized to include linear transformations of any complex vector space with a sesquilinear norm.

Note that the adjoint of an operator depends on the scalar product considered on the ${\displaystyle n}$ dimensional complex or real space ${\displaystyle K^n}$. If ${\displaystyle (\cdot \mid \cdot )}$ denotes the scalar product on ${\displaystyle K^n}$, then saying ${\displaystyle A}$ is skew-adjoint means that for all ${\displaystyle 𝐮,𝐯\in K^n}$ one has ${\displaystyle (A𝐮\mid 𝐯)=-(𝐮\mid A𝐯)}$.

Imaginary numbers can be thought of as skew-adjoint (since they are like ${\displaystyle 1\times 1}$ matrices), whereas real numbers correspond to self-adjoint operators.

For example, the following matrix is skew-Hermitian $${\displaystyle A=\left[\begin{array}{cc}-i& +2+i\\ -2+i& 0\end{array}\right]}$$ because $${\displaystyle -A=\left[\begin{array}{cc}i& -2-i\\ 2-i& 0\end{array}\right]=\left[\begin{array}{cc}\overline{-i}& \overline{-2+i}\\ \overline{2+i}& \bar{0}\end{array}\right]={\left[\begin{array}{cc}\overline{-i}& \overline{2+i}\\ \overline{-2+i}& \bar{0}\end{array}\right]}^{𝖳}=A^{𝖧}}$$

• The eigenvalues of a skew-Hermitian matrix are all purely imaginary (and possibly zero). Furthermore, skew-Hermitian matrices are normal. Hence they are diagonalizable and their eigenvectors for distinct eigenvalues must be orthogonal.^[3]
• All entries on the main diagonal of a skew-Hermitian matrix have to be pure imaginary; i.e., on the imaginary axis (the number zero is also considered purely imaginary).^[4]
• If ${\displaystyle A}$ and ${\displaystyle B}$ are skew-Hermitian, then Template:Tmath is skew-Hermitian for all real scalars ${\displaystyle a}$ and ${\displaystyle b}$.^[5]
• ${\displaystyle A}$ is skew-Hermitian if and only if ${\displaystyle iA}$ (or equivalently, ${\displaystyle -iA}$) is Hermitian.^[5]
• ${\displaystyle A}$ is skew-Hermitian if and only if the real part ${\displaystyle \mathrm{\Re }(A)}$ is skew-symmetric and the imaginary part ${\displaystyle \mathrm{\Im }(A)}$ is symmetric.
• If ${\displaystyle A}$ is skew-Hermitian, then ${\displaystyle A^k}$ is Hermitian if ${\displaystyle k}$ is an even integer and skew-Hermitian if ${\displaystyle k}$ is an odd integer.
• ${\displaystyle A}$ is skew-Hermitian if and only if ${\displaystyle {𝐱}^{𝖧}A𝐲=-\overline{{𝐲}^{𝖧}A𝐱}}$ for all vectors ${\displaystyle 𝐱,𝐲}$.
• If ${\displaystyle A}$ is skew-Hermitian, then the matrix exponential ${\displaystyle e^A}$ is unitary.
• The space of skew-Hermitian matrices forms the Lie algebra ${\displaystyle u(n)}$ of the Lie group ${\displaystyle U(n)}$.

• The sum of a square matrix and its conjugate transpose ${\displaystyle (A+A^{𝖧})}$ is Hermitian.
• The difference of a square matrix and its conjugate transpose ${\displaystyle (A-A^{𝖧})}$ is skew-Hermitian. This implies that the commutator of two Hermitian matrices is skew-Hermitian.
• An arbitrary square matrix ${\displaystyle C}$ can be written as the sum of a Hermitian matrix ${\displaystyle A}$ and a skew-Hermitian matrix ${\displaystyle B}$: $${\displaystyle C=A+B\text{with}A=\frac{1}{2}(C+C^{𝖧})\text{and}B=\frac{1}{2}(C-C^{𝖧})}$$

• Bivector (complex)
• Hermitian matrix
• Normal matrix
• Skew-symmetric matrix
• Unitary matrix

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