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In [[mathematics]], a [[complex number|complex]] [[Matrix_(mathematics)#Square_matrices|square]] [[matrix (mathematics)|matrix]] ''U'' is '''unitary''' if
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::<math>U^* U = UU^* = I \,</math>   
where ''I'' is the [[identity matrix]] and ''U''* is the [[conjugate transpose]]  of ''U''.
 
The real analogue of a unitary matrix is an [[orthonormal]] matrix.
 
==Properties==
For any unitary matrix ''U'', the following hold:
*Given two complex vectors ''x'' and ''y'', multiplication by ''U'' preserves their [[inner product]]; that is,
:<math>\langle Ux, Uy \rangle = \langle x, y \rangle</math>.
*''U'' is [[normal matrix|normal]]
*''U'' is [[diagonalizable matrix|diagonalizable]]; that is, ''U'' is [[similar matrix|unitarily similar]] to a diagonal matrix, as a consequence of the [[spectral theorem]].  Thus ''U'' has a decomposition of the form
::<math>U = VDV^*\;</math>
:where ''V'' is unitary and ''D'' is diagonal and unitary.
* <math>|\det(U)|=1</math>.
* Its [[Eigenvector#Eigenspaces_of_a_matrix|eigenspaces]] are orthogonal.
* For any positive [[integer]] ''n'', the set of all ''n'' by ''n'' unitary matrices with matrix multiplication forms a [[group (mathematics)|group]], called the [[unitary group]] ''U(n)''.
* Any square matrix with unit Euclidean norm is the average of two unitary matrices.<ref>{{cite journal| first1=Chi-Kwong|last1= Li |first2= Edward|last2= Poon|doi=10.1080/03081080290025507|title=Additive Decomposition of Real Matrices| year=2002| journal=Linear and Multilinear Algebra| volume=50| issue=4| pages=321–326}}</ref>
 
==Equivalent conditions==
If ''U'' is a square, complex matrix, then the following conditions are equivalent:
#''U'' is unitary
#''U''*  is unitary
#''U'' is invertible, with ''U''<sup> –1</sup>=''U''*.
# the columns of ''U'' form an [[orthonormal basis]] of <math>\mathbb{C}^n</math> with respect to the usual inner product
# the rows of ''U'' form an orthonormal basis of <math>\mathbb{C}^n</math> with respect to the usual inner product
# ''U'' is an [[isometry]] with respect to the usual norm
# ''U'' is a [[normal matrix]] with [[eigenvalues]] lying on the [[unit circle]].
 
==See also==
* [[Orthogonal matrix]]
* [[Hermitian matrix]]
* [[Symplectic matrix]]
* [[Unitary group]]
* [[Special unitary group]]
* [[Unitary operator]]
* [[Matrix decomposition]]
* [[Identity matrix]]
* [[Quantum gate]]
 
== References ==
{{reflist}}
 
== External links ==
* {{MathWorld|urlname=UnitaryMatrix |title=Unitary Matrix |last=Rowland|first= Todd}}
* {{SpringerEOM|id=U/u095540|title=Unitary matrix |first=O. A. |last=Ivanova}}
 
{{DEFAULTSORT:Unitary Matrix}}
[[Category:Matrices]]
[[Category:Unitary operators]]

Latest revision as of 12:01, 3 January 2015

Hello from Switzerland. I'm glad to be here. My first name is Rena.
I live in a small city called Egetswil in nothern Switzerland.
I was also born in Egetswil 29 years ago. Married in January 1999. I'm working at the university.

my web site Fifa 15 Coin Generator