Singular value

In mathematics, in particular functional analysis, the singular values of a compact operator $$T: X \rightarrow Y$$ acting between Hilbert spaces $$X$$ and $$Y$$, are the square roots of the (necessarily non-negative) eigenvalues of the self-adjoint operator $$T^*T$$ (where $$T^*$$ denotes the adjoint of $$T$$).

The singular values are non-negative real numbers, usually listed in decreasing order (σ1(T), σ2(T), …). The largest singular value σ1(T) is equal to the operator norm of T (see Min-max theorem).



If T acts on Euclidean space $$\Reals ^n$$, there is a simple geometric interpretation for the singular values: Consider the image by $$T$$ of the unit sphere; this is an ellipsoid, and the lengths of its semi-axes are the singular values of $$T$$ (the figure provides an example in $$\Reals^2$$).

The singular values are the absolute values of the eigenvalues of a normal matrix A, because the spectral theorem can be applied to obtain unitary diagonalization of $$A$$ as $$A = U\Lambda U^*$$. Therefore, $\sqrt{A^* A} = \sqrt{U \Lambda^* \Lambda U^*} = U \left

Most norms on Hilbert space operators studied are defined using singular values. For example, the Ky Fan-k-norm is the sum of first k singular values, the trace norm is the sum of all singular values, and the Schatten norm is the pth root of the sum of the pth powers of the singular values. Note that each norm is defined only on a special class of operators, hence singular values can be useful in classifying different operators.

In the finite-dimensional case, a matrix can always be decomposed in the form $$\mathbf{U\Sigma V^*}$$, where $$\mathbf{U}$$ and $$\mathbf{V^*}$$ are unitary matrices and $$\mathbf{\Sigma}$$ is a rectangular diagonal matrix with the singular values lying on the diagonal. This is the singular value decomposition.

Basic properties
For $$A \in \mathbb{C}^{m \times n}$$, and $$i = 1,2, \ldots, \min \{m,n\}$$.

Min-max theorem for singular values. Here $$U: \dim(U) = i$$ is a subspace of $$\mathbb{C}^n$$ of dimension $$i$$.


 * $$\begin{align}

\sigma_i(A) &= \min_{\dim(U)=n-i+1} \max_{\underset{\| x \|_2 = 1}{x \in U}} \left\| Ax \right\|_2. \\ \sigma_i(A) &= \max_{\dim(U)=i} \min_{\underset{\| x \|_2 = 1}{x \in U}} \left\| Ax \right\|_2. \end{align}$$

Matrix transpose and conjugate do not alter singular values.


 * $$\sigma_i(A) = \sigma_i\left(A^\textsf{T}\right) = \sigma_i\left(A^*\right).$$

For any unitary $$U \in \mathbb{C}^{m \times m}, V \in \mathbb{C}^{n \times n}.$$


 * $$\sigma_i(A) = \sigma_i(UAV).$$

Relation to eigenvalues:


 * $$\sigma_i^2(A) = \lambda_i\left(AA^*\right) = \lambda_i\left(A^*A\right).$$

Relation to trace:


 * $$\sum_{i=1}^n \sigma_i^2=\text{tr}\ A^\ast A$$.

If $$A^\top A$$ is full rank, the product of singular values is $$\sqrt{\det A^\top A}$$.

If $$A A^\top$$ is full rank, the product of singular values is $$\sqrt{\det A A^\top}$$.

If $$A$$ is full rank, the product of singular values is $$|\det A|$$.

Inequalities about singular values
See also.

Singular values of sub-matrices
For $$A \in \mathbb{C}^{m \times n}.$$
 * 1) Let $$B$$ denote $$A$$ with one of its rows or columns deleted. Then $$\sigma_{i+1}(A) \leq \sigma_i (B) \leq \sigma_i(A)$$
 * 2) Let $$B$$ denote $$A$$ with one of its rows and columns deleted. Then $$\sigma_{i+2}(A) \leq \sigma_i (B) \leq \sigma_i(A)$$
 * 3) Let $$B$$ denote an $$(m-k)\times(n-l)$$ submatrix of $$A$$. Then $$\sigma_{i+k+l}(A) \leq \sigma_i (B) \leq \sigma_i(A)$$

Singular values of A + B
For $$A, B \in \mathbb{C}^{m \times n}$$
 * 1) $$\sum_{i=1}^{k} \sigma_i(A + B) \leq \sum_{i=1}^{k} (\sigma_i(A) + \sigma_i(B)), \quad k=\min \{m,n\}$$
 * 2) $$\sigma_{i+j-1}(A + B) \leq \sigma_i(A) + \sigma_j(B). \quad i,j\in\mathbb{N},\ i + j - 1 \leq \min \{m,n\}$$

Singular values of AB
For $$A, B \in \mathbb{C}^{n \times n}$$ \prod_{i=n}^{i=n-k+1} \sigma_i(A) \sigma_i(B) &\leq \prod_{i=n}^{i=n-k+1} \sigma_i(AB) \\ \prod_{i=1}^k \sigma_i(AB) &\leq \prod_{i=1}^k \sigma_i(A) \sigma_i(B), \\ \sum_{i=1}^k \sigma_i^p(AB) &\leq \sum_{i=1}^k \sigma_i^p(A) \sigma_i^p(B), \end{align}$$
 * 1) $$\begin{align}
 * 1) $$\sigma_n(A) \sigma_i(B) \leq \sigma_i (AB) \leq \sigma_1(A) \sigma_i(B) \quad i = 1, 2, \ldots, n. $$

For $$A, B \in \mathbb{C}^{m \times n}$$ $$2 \sigma_i(A B^*) \leq \sigma_i \left(A^* A + B^* B\right), \quad i = 1, 2, \ldots, n. $$

Singular values and eigenvalues
For $$A \in \mathbb{C}^{n \times n}$$.
 * 1) See $$\lambda_i \left(A + A^*\right) \leq 2 \sigma_i(A), \quad i = 1, 2, \ldots, n.$$
 * 2) Assume $$\left|\lambda_1(A)\right| \geq \cdots \geq \left|\lambda_n(A)\right|$$. Then for $$k = 1, 2, \ldots, n$$:
 * 3) Weyl's theorem $$ \prod_{i=1}^k \left|\lambda_i(A)\right| \leq \prod_{i=1}^{k} \sigma_i(A).$$
 * 4) For $$p>0$$. $$ \sum_{i=1}^k \left|\lambda_i^p(A)\right| \leq \sum_{i=1}^{k} \sigma_i^p(A).$$

History
This concept was introduced by Erhard Schmidt in 1907. Schmidt called singular values "eigenvalues" at that time. The name "singular value" was first quoted by Smithies in 1937. In 1957, Allahverdiev proved the following characterization of the nth singular number:
 * $$\sigma_n(T) = \inf\big\{\, \|T-L\| : L\text{ is an operator of finite rank }<n \,\big\}.$$

This formulation made it possible to extend the notion of singular values to operators in Banach space. Note that there is a more general concept of s-numbers, which also includes Gelfand and Kolmogorov width.