The Glauber–Sudarshan P representation is a suggested way of writing down the phase space distribution of a quantum system in the phase space formulation of quantum mechanics. The P representation is the quasiprobability distribution in which observables are expressed in normal order. In quantum optics, this representation, formally equivalent to several other representations,[1] [2] is sometimes preferred over such alternative representations to describe light in optical phase space, because typical optical observables, such as the particle number operator, are naturally expressed in normal order. It is named after George Sudarshan[3] and Roy J. Glauber,[4] who worked on the topic in 1963.[5] Despite many useful applications in laser theory and coherence theory, the Sudarshan–Glauber P representation has the peculiarity that it is not always positive, and is not a bona-fide probability function.
See main article: article and Quasiprobability distribution. We wish to construct a function
P(\alpha)
\hat{\rho}
\{|\alpha\rangle\}
\hat{\rho}=\intP(\alpha)|{\alpha}\rangle\langle{\alpha}|d2\alpha, d2\alpha\equivd{\rmRe}(\alpha)d{\rmIm}(\alpha).
We also wish to construct the function such that the expectation value of a normally ordered operator satisfies the optical equivalence theorem. This implies that the density matrix should be in anti-normal order so that we can express the density matrix as a power series
\hat{\rho}A=\sumj,kcj,k ⋅ \hat{a}j\hat{a}\dagger.
Inserting the resolution of the identity
| \hat{I}= | 1 |
| \pi |
\int|{\alpha}\rangle\langle{\alpha}|d2\alpha,
| \dagger | ||
| \begin{align} \rho | )&= | |
| A(\hat{a},\hat{a} |
| 1 | |
| \pi |
\sumj,k\intcj,k ⋅ \hat{a}j|{\alpha}\rangle\langle{\alpha}|\hat{a}\daggerd2\alpha\\ &=
| 1 | |
| \pi |
\sumj,k\intcj,k ⋅ \alphaj|{\alpha}\rangle\langle{\alpha}|\alpha*kd2\alpha\\ &=
| 1 | |
| \pi |
\int\sumj,kcj,k ⋅ \alphaj\alpha*k|{\alpha}\rangle\langle{\alpha}|d2\alpha\\ &=
| 1 | |
| \pi |
\int
| *)|{\alpha}\rangle | |
| \rho | |
| A(\alpha,\alpha |
\langle{\alpha}|d2\alpha,\end{align}
| P(\alpha)= | 1 |
| \pi |
| *). | |
| \rho | |
| A(\alpha,\alpha |
More useful integral formulas for are necessary for any practical calculation. One method[6] is to define the characteristic function
\chiN(\beta)=\operatorname{tr}(\hat{\rho} ⋅ ei\beta ⋅ \hat{a\dagger
| P(\alpha)= | 1 |
| \pi2 |
\int\chiN(\beta)
| -\beta\alpha*+\beta*\alpha | |
| e |
d2\beta.
Another useful integral formula for is[7]
| P(\alpha)= |
| ||||
| \pi2 |
\int\langle-\beta|\hat{\rho}|\beta\rangle
| |\beta|2-\beta\alpha*+\beta*\alpha | |
| e |
d2\beta.
Note that both of these integral formulas do not converge in any usual sense for "typical" systems . We may also use the matrix elements of
\hat{\rho}
\{|n\rangle\}
P(\alpha)=\sumn\sumk\langlen|\hat{\rho}|k\rangle
| \sqrt{n!k! | |
If the quantum system has a classical analog, e.g. a coherent state or thermal radiation, then is non-negative everywhere like an ordinary probability distribution. If, however, the quantum system has no classical analog, e.g. an incoherent Fock state or entangled system, then is negative somewhere or more singular than a Dirac delta function. (By a theorem of Schwartz, distributions that are more singular than the Dirac delta function are always negative somewhere.) Such "negative probability" or high degree of singularity is a feature inherent to the representation and does not diminish the meaningfulness of expectation values taken with respect to . Even if does behave like an ordinary probability distribution, however, the matter is not quite so simple. According to Mandel and Wolf: "The different coherent states are not [mutually] orthogonal, so that even if
P(\alpha)
From statistical mechanics arguments in the Fock basis, the mean photon number of a mode with wavevector and polarization state for a black body at temperature is known to be
\langle\hat{n}k,s\rangle=
| 1 | ||||||
|
.
P(\{\alphak,s\})=\prodk,s
| 1 | |
| \pi\langle\hat{n |
k,s\rangle}
| -|\alpha|2/\langle\hat{n | |
| e | |
| k,s |
\rangle}.
Even very simple-looking states may exhibit highly non-classical behavior. Consider a superposition of two coherent states
|\psi\rangle=c0|\alpha0\rangle+c1|\alpha1\rangle
| 2+2e | |
| 1=|c | |
| 1| |
| |||||||
\operatorname{Re}\left(
| *c | |
| c | |
| 1 |
| |||||||
| e |
\right).
|\alpha0\rangle
|\alpha1\rangle
\langle-\alpha|\hat{\rho}|\alpha\rangle=\langle-\alpha|\psi\rangle\langle\psi|\alpha\rangle
\begin{align}P(\alpha)={}&
| 2\delta | |
| |c | |
| 0| |
| 2(\alpha-\alpha | |
| 0)+|c |
| 2\delta | |
| 1| |
| 2(\alpha-\alpha | |
| 1) |
\\[5pt] &{}
| |||||||||||||||||||||||||
| +2c | |||||||||||||||||||||||||
| 1 e |
| ||||||||||||||||
| e |
| (\alpha0-\alpha1) ⋅ \partial/\partial(2\alpha-\alpha0-\alpha1) | |
| e |
⋅
| 2(2\alpha-\alpha | |
| \delta | |
| 0-\alpha |
1)\\[5pt] &{}+2c0c
| * e | |
| 1 |
| |||||||||||||||||||||||||
| ||||||||||||||||
| e |
| (\alpha1-\alpha0) ⋅ \partial/\partial(2\alpha-\alpha0-\alpha1) | |
| e |
⋅
| 2(2\alpha-\alpha | |
| \delta | |
| 0-\alpha |
1). \end{align}
Despite having infinitely many derivatives of delta functions, still obeys the optical equivalence theorem. If the expectation value of the number operator, for example, is taken with respect to the state vector or as a phase space average with respect to, the two expectation values match:
\begin{align}\langle\psi|\hat{n}|\psi\rangle&=\intP(\alpha)|\alpha|2d2\alpha\\ &=|c0\alpha
| 2+|c | |
| 1\alpha |
| 2+2e | |
| 1| |
| |||||||
\operatorname{Re}\left(
| *c | |
| c | |
| 1 |
| *\alpha | |
| \alpha | |
| 1 |
| |||||||
| e |
\right).\end{align}