Unduloid

In linear algebra, skew-Hamiltonian matrices are special matrices which correspond to skew-symmetric bilinear forms on a symplectic vector space.

Let V be a vector space, equipped with a symplectic form $Ω$ . Such a space must be even-dimensional. A linear map $A : V \mapsto V$ is called a skew-Hamiltonian operator with respect to $Ω$ if the form $x, y \mapsto Ω (A (x), y)$ is skew-symmetric.

Choose a basis $e_{1}, . . . e_{2 n}$ in V, such that $Ω$ is written as $\sum_{i} e_{i} \land e_{n + i}$ . Then a linear operator is skew-Hamiltonian with respect to $Ω$ if and only if its matrix A satisfies $A^{T} J = J A$ , where J is the skew-symmetric matrix

J = [\begin{matrix} 0 & I_{n} \\ - I_{n} & 0 \end{matrix}]

and I_n is the $n \times n$ identity matrix.^[1] Such matrices are called skew-Hamiltonian.

The square of a Hamiltonian matrix is skew-Hamiltonian. The converse is also true: every skew-Hamiltonian matrix can be obtained as the square of a Hamiltonian matrix.^[1]^[2]

Notes

↑ ^1.0 ^1.1 William C. Waterhouse, The structure of alternating-Hamiltonian matrices, Linear Algebra and its Applications, Volume 396, 1 February 2005, Pages 385-390
↑ Heike Faßbender, D. Steven Mackey, Niloufer Mackey and Hongguo Xu Hamiltonian Square Roots of Skew-Hamiltonian Matrices, Linear Algebra and its Applications 287, pp. 125 - 159, 1999

Template:Linear-algebra-stub

[waterhouse-1] 1.0 ^1.1 William C. Waterhouse, The structure of alternating-Hamiltonian matrices, Linear Algebra and its Applications, Volume 396, 1 February 2005, Pages 385-390

[2] Heike Faßbender, D. Steven Mackey, Niloufer Mackey and Hongguo Xu Hamiltonian Square Roots of Skew-Hamiltonian Matrices, Linear Algebra and its Applications 287, pp. 125 - 159, 1999

[1]

[2]

Unduloid

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