In mathematics, a complex square matrix A is **normal** if it commutes with its conjugate transpose *A*^{*}:

The concept of normal matrices can be extended to normal operators on infinite dimensional normed spaces and to normal elements in C*-algebras. As in the matrix case, normality means commutativity is preserved, to the extent possible, in the noncommutative setting. This makes normal operators, and normal elements of C*-algebras, more amenable to analysis.

The spectral theorem states that a matrix is normal if and only if it is unitarily similar to a diagonal matrix, and therefore any matrix A satisfying the equation *A*^{*}*A* = *AA*^{*} is diagonalizable.

## Special cases

Among complex matrices, all unitary, Hermitian, and skew-Hermitian matrices are normal. Likewise, among real matrices, all orthogonal, symmetric, and skew-symmetric matrices are normal. However, it is *not* the case that all normal matrices are either unitary or (skew-)Hermitian. For example,

is neither unitary, Hermitian, nor skew-Hermitian, yet it is normal because

## Consequences

**Proposition**: A normal triangular matrix is diagonal.

**Proof**: Let A be any normal upper triangular matrix. Since- using subscript notation, one can write the equivalent expression using instead the ith unit vector () to select the ith row and ith column:
- The expression
- is equivalent, and so is
- which shows that the ith row must have the same norm as the ith column.
- Consider
*i*= 1. The first entry of row 1 and column 1 are the same (because of normality), and the rest of column 1 is zero (because of triangularity). This implies the first row must be zero for entries 2 through n. Continuing this argument for row–column pairs 2 through n shows A is diagonal.**◻**

The concept of normality is important because normal matrices are precisely those to which the spectral theorem applies:

**Proposition.**A matrix A is normal if and only if there exists a diagonal matrix Λ and a unitary matrix U such that*A*=*U*Λ*U*^{*}.

The diagonal entries of Λ are the eigenvalues of A, and the columns of U are the eigenvectors of A. The matching eigenvalues in Λ come in the same order as the eigenvectors are ordered as columns of U.

Another way of stating the spectral theorem is to say that normal matrices are precisely those matrices that can be represented by a diagonal matrix with respect to a properly chosen orthonormal basis of **C**^{n}. Phrased differently: a matrix is normal if and only if its eigenspaces span **C**^{n} and are pairwise orthogonal with respect to the standard inner product of **C**^{n}.

The spectral theorem for normal matrices is a special case of the more general Schur decomposition which holds for all square matrices. Let A be a square matrix. Then by Schur decomposition it is unitary similar to an upper-triangular matrix, say, B. If A is normal, so is B. But then B must be diagonal, for, as noted above, a normal upper-triangular matrix is diagonal.

The spectral theorem permits the classification of normal matrices in terms of their spectra, for example:

**Proposition.**A normal matrix is unitary if and only if all of its eigenvalues (its spectrum) lie on the unit circle of the complex plane.

**Proposition.**A normal matrix is self-adjoint if and only if its spectrum is contained in . In other words: A normal matrix is Hermitian if and only if all its eigenvalues are real.

In general, the sum or product of two normal matrices need not be normal. However, the following holds:

**Proposition.**If A and B are normal with*AB*=*BA*, then both*AB*and*A*+*B*are also normal. Furthermore there exists a unitary matrix U such that*UAU*^{*}and*UBU*^{*}are diagonal matrices. In other words A and B are simultaneously diagonalizable.

In this special case, the columns of *U*^{*} are eigenvectors of both A and B and form an orthonormal basis in **C**^{n}. This follows by combining the theorems that, over an algebraically closed field, commuting matrices are simultaneously triangularizable and a normal matrix is diagonalizable – the added result is that these can both be done simultaneously.

## Equivalent definitions

It is possible to give a fairly long list of equivalent definitions of a normal matrix. Let A be a *n* × *n* complex matrix. Then the following are equivalent:

- A is normal.
- A is diagonalizable by a unitary matrix.
- There exists a set of eigenvectors of A which forms an orthonormal basis for
**C**^{n}. - for every
**x**. - The Frobenius norm of A can be computed by the eigenvalues of A: .
- The Hermitian part 1/2(
*A*+*A*^{*}) and skew-Hermitian part 1/2(*A*−*A*^{*}) of A commute. *A*^{*}is a polynomial (of degree ≤*n*− 1) in A.^{[a]}*A*^{*}=*AU*for some unitary matrix U.^{[1]}- U and P commute, where we have the polar decomposition
*A*=*UP*with a unitary matrix U and some positive semidefinite matrix P. - A commutes with some normal matrix N with distinct eigenvalues.
*σ*= |_{i}*λ*| for all 1 ≤_{i}*i*≤*n*where A has singular values*σ*_{1}≥ ⋯ ≥*σ*and eigenvalues |_{n}*λ*_{1}| ≥ ⋯ ≥ |*λ*|._{n}^{[2]}

Some but not all of the above generalize to normal operators on infinite-dimensional Hilbert spaces. For example, a bounded operator satisfying (9) is only quasinormal.

## Analogy

It is occasionally useful (but sometimes misleading) to think of the relationships of different kinds of normal matrices as analogous to the relationships between different kinds of complex numbers:

- Invertible matrices are analogous to non-zero complex numbers
- The conjugate transpose is analogous to the complex conjugate
- Unitary matrices are analogous to complex numbers on the unit circle
- Hermitian matrices are analogous to real numbers
- Hermitian positive definite matrices are analogous to positive real numbers
- Skew Hermitian matrices are analogous to purely imaginary numbers

As a special case, the complex numbers may be embedded in the normal 2×2 real matrices by the mapping

which preserves addition and multiplication. It is easy to check that this embedding respects all of the above analogies.

## See also

## Notes

**^**Proof. When is normal, use Lagrange's interpolation formula to construct a polynomial such that , where are the eigenvalues of .

## Citations

**^**Horn & Johnson (1985), p. 109**^**Horn & Johnson (1991), p. 157

## Sources

- Horn, Roger Alan; Johnson, Charles Royal (1985),
*Matrix Analysis*, Cambridge University Press, ISBN 978-0-521-38632-6. - Horn, Roger Alan; Johnson, Charles Royal (1991).
*Topics in Matrix Analysis*. Cambridge University Press. ISBN 978-0-521-30587-7.