In physics, a quantum amplifier is an amplifier that uses quantum mechanical methods to amplify a signal; examples include the active elements of lasers and optical amplifiers.
The main properties of the quantum amplifier are its amplification coefficient and uncertainty. These parameters are not independent; the higher the amplification coefficient, the higher the uncertainty (noise). In the case of lasers, the uncertainty corresponds to the amplified spontaneous emission of the active medium. The unavoidable noise of quantum amplifiers is one of the reasons for the use of digital signals in optical communications and can be deduced from the fundamentals of quantum mechanics.
An amplifier increases the amplitude of whatever goes through it. While classical amplifiers take in classical signals, quantum amplifiers take in quantum signals, such as coherent states. This does not necessarily mean that the output is a coherent state; indeed, typically it is not. The form of the output depends on the specific amplifier design. Besides amplifying the intensity of the input, quantum amplifiers can also increase the quantum noise present in the signal.
The physical electric field in a paraxial single-mode pulse can be approximated with superposition of modes; the electric field
~E\rm~
\vecE\rm(\vecx)~=~\vece~\hata~M(\vecx)~\exp(ikz-{\rmi}\omegat)~+~{\rmHermitian~conjugate}~
where
~\vecx=\{x1,x2,z\}~
~\vece~
~k~
~\hata~
~M(\vecx)~
The analysis of the noise in the system is made with respect to the mean value of the annihilation operator. To obtain the noise, one solves for the real and imaginary parts of the projection of the field to a given mode
~M(\vecx)~
Assume that the mean value of the initial field is
~{\left\langle\hata\right\rangle\rm
\hatU
~|{\rminitial}\rangle~
~|{\rmfinal}\rangle~
~|{\rmfinal}\rangle=U|\rminitial\rangle
This equation describes the quantum amplifier in the Schrödinger representation.
The amplification depends on the mean value
~\langle\hata\rangle~
~\hata~
~\langle\hata\dagger\hata\rangle-\langle\hata\dagger\rangle\langle\hata\rangle~
~G~
G=
| \left\langle\hata\right\rangle\rm | |
| \left\langle\hata\right\rangle\rm |
The can be written also in the Heisenberg representation; the changes are attributed to the amplification of the field operator. Thus, the evolution of the operator A is given by
~\hatA=\hatU\dagger\hata\hatU~
~G=
| \left\langle\hatA\right\rangle\rm | |
| \left\langle\hata\right\rangle\rm |
~
In general, the gain
~G~
~\alpha~
~~|{\rminitial}\rangle=|\alpha\rangle~
In the following, the Heisenberg representation is used; all brackets are assumed to be evaluated with respect to the initial coherent state.
{\rmnoise}=\langle\hatA\dagger\hatA\rangle-\langle\hatA\dagger\rangle\langle\hatA\rangle-\left(\langle\hata\dagger\hata\rangle-\langle\hata\dagger\rangle\langle\hata\rangle\right)
The expectation values are assumed to be evaluated with respect to the initial coherent state. This quantity characterizes the increase of the uncertainty of the field due to amplification. As the uncertainty of the field operator does not depend on its parameter, the quantity above shows how much output field differs from a coherent state.
Linear phase-invariant amplifiers may be described as follows. Assume that the unitary operator
~\hatU~
~\hata~
~\hatA={\hatU}\dagger\hata\hatU~
~\hatA=c\hata+s\hatb\dagger,
where
~c~
~s~
~\hatb\dagger~
~c~
~s~
~\hatU~
\hatA\hatA\dagger-\hatA\dagger\hatA=\hata\hata\dagger-\hata\dagger\hata=1.
From the unitarity of
~\hatU~
~\hatb~
~\hatb\hatb\dagger-\hatb\dagger\hatb=1~
The c-numbers are then
~c2-s2=1~.
Hence, the phase-invariant amplifier acts by introducing an additional mode to the field, with a large amount of stored energy, behaving as a boson. Calculating the gain and the noise of this amplifier, one finds
~~G=c~~
and
~~{\rmnoise}=c2-1.
The coefficient
~~g=|G|2~~
g-1
The linear amplifier has an advantage over the multi-mode amplifier: if several modes of a linear amplifier are amplified by the same factor, the noise in each mode is determined independently;that is, modes in a linear quantum amplifier are independent.
To obtain a large amplification coefficient with minimal noise, one may use homodyne detection, constructing a field state with known amplitude and phase, corresponding to the linear phase-invariant amplifier.[2] The uncertainty principle sets the lower bound of quantum noise in an amplifier. In particular, the output of a laser system and the output of an optical generator are not coherent states.
Nonlinear amplifiers do not have a linear relation between their input and output. The maximum noise of a nonlinear amplifier cannot be much smaller than that of an idealized linear amplifier.[1] This limit is determined by the derivatives of the mapping function; a larger derivative implies an amplifier with greater uncertainty.[3] Examples include most lasers, which include near-linear amplifiers, operating close to their threshold and thus exhibiting large uncertainty and nonlinear operation. As with the linear amplifiers, they may preserve the phase and keep the uncertainty low, but there are exceptions. These include parametric oscillators, which amplify while shifting the phase of the input.