Unitary operator
In functional analysis, a unitary operator is a surjective bounded operator on a Hilbert space that preserves the inner product.
Non-trivial examples include rotations, reflections, and the Fourier operator.
Unitary operators generalize unitary matrices.
Unitary operators are usually taken as operating on a Hilbert space, but the same notion serves to define the concept of isomorphism between Hilbert spaces.
Definition
Definition 1. A unitary operator is a bounded linear operator on a Hilbert space that satisfies, where is the adjoint of, and is the identity operator.The weaker condition defines an isometry. The other weaker condition,, defines a coisometry. Thus a unitary operator is a bounded linear operator that is both an isometry and a coisometry, or, equivalently, a surjective isometry.
An equivalent definition is the following:
Definition 2. A unitary operator is a bounded linear operator on a Hilbert space for which the following hold:
- is surjective, and
- preserves the inner product of the Hilbert space,. In other words, for all vectors and in we have:
- :
The following, seemingly weaker, definition is also equivalent:
Definition 3. A unitary operator is a bounded linear operator on a Hilbert space for which the following hold:
- the range of is dense in, and
- preserves the inner product of the Hilbert space,. In other words, for all vectors and in we have:
- :
Thus, unitary operators are just automorphisms of Hilbert spaces, i.e., they preserve the structure of the space on which they act. The group of all unitary operators from a given Hilbert space to itself is sometimes referred to as the Hilbert group of, denoted or.
Examples
- The identity function is trivially a unitary operator.
- Rotations in are the simplest nontrivial example of unitary operators. Rotations do not change the length of a vector or the angle between two vectors. This example can be expanded to. In even higher dimensions, this can be extended to the Givens rotation.
- Reflections, like the Householder transformation.
- times a Hadamard matrix.
- In general, any operator in a Hilbert space that acts by permuting an orthonormal basis is unitary. In the finite dimensional case, such operators are the permutation matrices.
- On the vector space of complex numbers, multiplication by a number of absolute value, that is, a number of the form for, is a unitary operator. is referred to as a phase, and this multiplication is referred to as multiplication by a phase. Notice that the value of modulo does not affect the result of the multiplication, and so the independent unitary operators on are parametrized by a circle. The corresponding group, which, as a set, is the circle, is called.
- The Fourier operator is a unitary operator, i.e. the operator that performs the Fourier transform. This follows from Parseval's theorem.
- Quantum logic gates are unitary operators. Not all gates are Hermitian.
- More generally, unitary matrices are precisely the unitary operators on finite-dimensional Hilbert spaces, so the notion of a unitary operator is a generalization of the notion of a unitary matrix. Orthogonal matrices are the special case of unitary matrices in which all entries are real. They are the unitary operators on.
- The bilateral shift on the sequence space indexed by the integers is unitary.
- The unilateral shift is an isometry; its conjugate is a coisometry.
- Unitary operators are used in unitary representations.
- A unitary element is a generalization of a unitary operator. In a unital algebra, an element of the algebra is called a unitary element if, where is the multiplicative identity element.
- Any composition of the above.
Linearity
Analogously we obtain
Properties
- The spectrum of a unitary operator lies on the unit circle. That is, for any complex number in the spectrum, one has. This can be seen as a consequence of the spectral theorem for normal operators. By the theorem, is unitarily equivalent to multiplication by a Borel-measurable on, for some finite measure space. Now implies, -a.e. This shows that the essential range of, therefore the spectrum of, lies on the unit circle.
- A linear map is unitary if it is surjective and isometric.