7  Orthogonality and Orthogonal Matrix

Orthogonality

A set of non-zero vectors v_{1}, \dots, v_{k} are orthogonal if

\langle v_{i}, v_{j} \rangle = 0, \quad \forall i \neq j.

Properties of orthogonality

If v_{1}, \dots, v_{k} are orthogonal vectors,

  • v_{1}, \dots, v_{k} are also linearly independent.

    TODO

  • Suppose \mathcal{S} is a subspace with \text{dim} (S) = n and v_{1}, \dots, v_{k} \in \mathcal{S}, then the set \{ v_{1}, \dots, v_{k} \} forms a basis of \mathcal{S}. Then, \{ v_{1}, \dots, v_{k} \} is an orthogonal basis of \mathcal{S}.

    TODO

Representing vectors using orthogonal basis

Suppose \mathcal{S} is a subspace and \{ v_{1}, \dots, v_{n} \} is an orthogonal basis of \mathcal{S}, any vector v \in \mathcal{S} can be represented using \{ v_{1}, \dots, v_{n} \}:

v = \sum_{i=1}^{n} \alpha_{i} v_{i},

where

\alpha_{i} = \frac{ \langle v, v_{i} \rangle }{ \lVert v_{i} \rVert_{ip}^{2} }

TODO

Orthogonal matrix

A set of vectors v_{1}, \dots, v_{k} are orthonormal if all vectors in the set are orthogonal to each other, and each vector has the inner product norm of 1.

A square real (complex) matrix \mathbf{U} is orthogonal (unitary) if and only if \mathbf{U} has orthonormal columns.

Properties of orthogonal matrix

  • The matrix \mathbf{U} is orthogonal if and only if \mathbf{U}^{H} = \mathbf{U}^{-1}.

    By definition, \mathbf{U} has orthogonal columns and thus linearly independent columns. By the rank property, \mathbf{U} has a unique inverse matrix \mathbf{U}^{-1} such that

    \mathbf{U}^{-1} \mathbf{U} = \mathbf{I}_{n \times n}.

    Since by definition we know

    \mathbf{U}^{H} \mathbf{U} = \mathbf{I}_{n \times n},

    then it must follow that

    \mathbf{U}^{H} = \mathbf{U}^{-1}.

    The reverse can be proved backward following the procedure above.

  • The matrix \mathbf{U} is orthogonal if and only if \mathbf{U}^{H} \mathbf{U} = \mathbf{U} \mathbf{U}^{H} = \mathbf{I}_{n \times n}.

    Following the unitary matrix property, the inverse \mathbf{U}^{-1} can be both left and right inverse

    \mathbf{U}^{-1} \mathbf{U} = \mathbf{U} \mathbf{U}^{-1} = \mathbf{I}.

    Replacing \mathbf{U}^{-1} with \mathbf{U}^{H}, we have the results:

    \mathbf{U}^{H} \mathbf{U} = \mathbf{U} \mathbf{U}^{H} = \mathbf{I}.

  • The matrix \mathbf{U} is orthogonal if and only if \mathbf{U} \mathbf{x} doesn’t change the length of \mathbf{x}:

    \lVert \mathbf{U} \mathbf{x} \rVert = \lVert \mathbf{x} \rVert.

    \begin{aligned} \lVert \mathbf{U} \mathbf{x} \rVert & = \sqrt{\lVert \mathbf{U} \mathbf{x} \rVert^{2}} \\ & = \sqrt{\mathbf{x}^{H} \mathbf{U}^{H} \mathbf{U} \mathbf{x}} \\ & = \sqrt{\mathbf{x}^{H} \mathbf{I} \mathbf{x}} & [\mathbf{U}^{H} \mathbf{U} = \mathbf{I}] \\ & = \sqrt{\mathbf{x}^{H} \mathbf{x}} \\ & = \sqrt{\lVert \mathbf{x} \rVert^{2}} \\ & = \lVert \mathbf{x} \rVert \end{aligned}