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Glauber–Sudarshan P representation

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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, 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 and Roy J. Glauber, who worked on the topic in 1963. 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.

Definition

Main article: Quasiprobability distribution

We wish to construct a function P ( α ) {\displaystyle P(\alpha )} with the property that the density matrix ρ ^ {\displaystyle {\hat {\rho }}} is diagonal in the basis of coherent states { | α } {\displaystyle \{|\alpha \rangle \}} , i.e.,

ρ ^ = P ( α ) | α α | d 2 α , d 2 α d R e ( α ) d I m ( α ) . {\displaystyle {\hat {\rho }}=\int P(\alpha )|{\alpha }\rangle \langle {\alpha }|\,d^{2}\alpha ,\qquad d^{2}\alpha \equiv d\,{\rm {Re}}(\alpha )\,d\,{\rm {Im}}(\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

ρ ^ A = j , k c j , k a ^ j a ^ k . {\displaystyle {\hat {\rho }}_{A}=\sum _{j,k}c_{j,k}\cdot {\hat {a}}^{j}{\hat {a}}^{\dagger k}.}

Inserting the resolution of the identity

I ^ = 1 π | α α | d 2 α , {\displaystyle {\hat {I}}={\frac {1}{\pi }}\int |{\alpha }\rangle \langle {\alpha }|\,d^{2}\alpha ,}

we see that

ρ A ( a ^ , a ^ ) = 1 π j , k c j , k a ^ j | α α | a ^ k d 2 α = 1 π j , k c j , k α j | α α | α k d 2 α = 1 π j , k c j , k α j α k | α α | d 2 α = 1 π ρ A ( α , α ) | α α | d 2 α , {\displaystyle {\begin{aligned}\rho _{A}({\hat {a}},{\hat {a}}^{\dagger })&={\frac {1}{\pi }}\sum _{j,k}\int c_{j,k}\cdot {\hat {a}}^{j}|{\alpha }\rangle \langle {\alpha }|{\hat {a}}^{\dagger k}\,d^{2}\alpha \\&={\frac {1}{\pi }}\sum _{j,k}\int c_{j,k}\cdot \alpha ^{j}|{\alpha }\rangle \langle {\alpha }|\alpha ^{*k}\,d^{2}\alpha \\&={\frac {1}{\pi }}\int \sum _{j,k}c_{j,k}\cdot \alpha ^{j}\alpha ^{*k}|{\alpha }\rangle \langle {\alpha }|\,d^{2}\alpha \\&={\frac {1}{\pi }}\int \rho _{A}(\alpha ,\alpha ^{*})|{\alpha }\rangle \langle {\alpha }|\,d^{2}\alpha ,\end{aligned}}}

and thus we formally assign

P ( α ) = 1 π ρ A ( α , α ) . {\displaystyle P(\alpha )={\frac {1}{\pi }}\rho _{A}(\alpha ,\alpha ^{*}).}

More useful integral formulas for P are necessary for any practical calculation. One method is to define the characteristic function

χ N ( β ) = tr ( ρ ^ e i β a ^ e i β a ^ ) {\displaystyle \chi _{N}(\beta )=\operatorname {tr} ({\hat {\rho }}\cdot e^{i\beta \cdot {\hat {a}}^{\dagger }}e^{i\beta ^{*}\cdot {\hat {a}}})}

and then take the Fourier transform

P ( α ) = 1 π 2 χ N ( β ) e β α + β α d 2 β . {\displaystyle P(\alpha )={\frac {1}{\pi ^{2}}}\int \chi _{N}(\beta )e^{-\beta \alpha ^{*}+\beta ^{*}\alpha }\,d^{2}\beta .}

Another useful integral formula for P is

P ( α ) = e | α | 2 π 2 β | ρ ^ | β e | β | 2 β α + β α d 2 β . {\displaystyle P(\alpha )={\frac {e^{|\alpha |^{2}}}{\pi ^{2}}}\int \langle -\beta |{\hat {\rho }}|\beta \rangle e^{|\beta |^{2}-\beta \alpha ^{*}+\beta ^{*}\alpha }\,d^{2}\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 ρ ^ {\displaystyle {\hat {\rho }}} in the Fock basis { | n } {\displaystyle \{|n\rangle \}} . The following formula shows that it is always possible to write the density matrix in this diagonal form without appealing to operator orderings using the inversion (given here for a single mode),

P ( α ) = n k n | ρ ^ | k n ! k ! 2 π r ( n + k ) ! e r 2 i ( n k ) θ [ ( r ) n + k δ ( r ) ] , {\displaystyle P(\alpha )=\sum _{n}\sum _{k}\langle n|{\hat {\rho }}|k\rangle {\frac {\sqrt {n!k!}}{2\pi r(n+k)!}}e^{r^{2}-i(n-k)\theta }\left,}

where r and θ are the amplitude and phase of α. Though this is a full formal solution of this possibility, it requires infinitely many derivatives of Dirac delta functions, far beyond the reach of any ordinary tempered distribution theory.

Discussion

If the quantum system has a classical analog, e.g. a coherent state or thermal radiation, then P 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 P 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 P. Even if P 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 orthogonal, so that even if P ( α ) {\displaystyle P(\alpha )} behaved like a true probability density , it would not describe probabilities of mutually exclusive states."

Examples

Fock states

Fock states, | ψ = | n {\displaystyle |\psi \rangle =|n\rangle } for integer n {\displaystyle n} , correspond to a highly singular P distribution, which can be written as P n ( α , α ) = e | α | 2 n ! 2 n α n α n δ 2 ( α ) . {\displaystyle P_{n}(\alpha ,\alpha ^{*})={\frac {e^{|\alpha |^{2}}}{n!}}{\frac {\partial ^{2n}}{\partial \alpha ^{*n}\,\partial \alpha ^{n}}}\delta ^{2}(\alpha ).} While this is not a function, this expression corresponds to a tempered distribution. In particular for the vacuum state | 0 {\displaystyle |0\rangle } the P distribution is a Dirac delta function at the origin, as P 0 ( α , α ) = e | α | 2 δ 2 ( α ) = δ 2 ( α ) {\displaystyle P_{0}(\alpha ,\alpha ^{*})=e^{|\alpha |^{2}}\delta ^{2}(\alpha )=\delta ^{2}(\alpha )} . Similarly, the Fock state | 1 {\displaystyle |1\rangle } gives P 1 ( α , α ) = e | α | 2 2 α α δ 2 ( α ) = δ 2 ( α ) + 2 α α δ 2 ( α ) . {\displaystyle P_{1}(\alpha ,\alpha ^{*})=e^{|\alpha |^{2}}{\frac {\partial ^{2}}{\partial \alpha \partial \alpha ^{*}}}\delta ^{2}(\alpha )=\delta ^{2}(\alpha )+{\frac {\partial ^{2}}{\partial \alpha \partial \alpha ^{*}}}\delta ^{2}(\alpha ).} We can also easily verify that the above expression for P n {\displaystyle P_{n}} works more generally observing that d 2 α ( e | α | 2 n ! 2 n α n α n δ 2 ( α ) ) | α α | = j , k = 0 | j k | n ! j ! k ! d 2 α ( 2 n α n α n δ 2 ( α ) ) α j α k , {\displaystyle \int \mathrm {d} ^{2}\alpha \left({\frac {e^{|\alpha |^{2}}}{n!}}{\frac {\partial ^{2n}}{\partial \alpha ^{n}\partial \alpha ^{*n}}}\delta ^{2}(\alpha )\right)|\alpha \rangle \!\langle \alpha |=\sum _{j,k=0}^{\infty }{\frac {|j\rangle \!\langle k|}{n!{\sqrt {j!k!}}}}\int \mathrm {d} ^{2}\alpha \left({\frac {\partial ^{2n}}{\partial \alpha ^{n}\partial \alpha ^{*n}}}\delta ^{2}(\alpha )\right)\alpha ^{j}\alpha ^{*k},} together with the identity d 2 α ( 2 n α n α n δ 2 ( α ) ) α j α k = 2 n α n α n ( α j α k ) | α = 0 = n ! 2 δ j , n δ k , n . {\displaystyle \int \mathrm {d} ^{2}\alpha \left({\frac {\partial ^{2n}}{\partial \alpha ^{n}\partial \alpha ^{*n}}}\delta ^{2}(\alpha )\right)\alpha ^{j}\alpha ^{*k}=\left.{\frac {\partial ^{2n}}{\partial \alpha ^{n}\partial \alpha ^{*n}}}(\alpha ^{j}\alpha ^{*k})\right\vert _{\alpha =0}=n!^{2}\delta _{j,n}\delta _{k,n}.} The same reasoning can be used to show more generally that the P function of the operators | n m | {\displaystyle |n\rangle \!\langle m|} is given by P n , m ( α , α ) = e | α | 2 n ! m ! n + m α n α m δ 2 ( α ) . {\displaystyle P_{n,m}(\alpha ,\alpha ^{*})={\frac {e^{|\alpha |^{2}}}{\sqrt {n!m!}}}{\frac {\partial ^{n+m}}{\partial \alpha ^{n}\partial \alpha ^{*m}}}\delta ^{2}(\alpha ).}

Another concise formal expression for the P function of Fock states using the Laguerre polynomials is P n ( α , α ) = L n ( 1 4 α α ) δ 2 ( α ) . {\displaystyle P_{n}(\alpha ,\alpha ^{*})=L_{n}(-{\frac {1}{4}}\partial _{\alpha }\partial _{\alpha ^{*}})\delta ^{2}(\alpha ).}

Thermal radiation

From statistical mechanics arguments in the Fock basis, the mean photon number of a mode with wavevector k and polarization state s for a black body at temperature T is known to be

n ^ k , s = 1 e ω / k B T 1 . {\displaystyle \langle {\hat {n}}_{\mathbf {k} ,s}\rangle ={\frac {1}{e^{\hbar \omega /k_{B}T}-1}}.}

The P representation of the black body is

P ( { α k , s } ) = k , s 1 π n ^ k , s e | α | 2 / n ^ k , s . {\displaystyle P(\{\alpha _{\mathbf {k} ,s}\})=\prod _{\mathbf {k} ,s}{\frac {1}{\pi \langle {\hat {n}}_{\mathbf {k} ,s}\rangle }}e^{-|\alpha |^{2}/\langle {\hat {n}}_{\mathbf {k} ,s}\rangle }.}

In other words, every mode of the black body is normally distributed in the basis of coherent states. Since P is positive and bounded, this system is essentially classical. This is actually quite a remarkable result because for thermal equilibrium the density matrix is also diagonal in the Fock basis, but Fock states are non-classical.

Highly singular example

Even very simple-looking states may exhibit highly non-classical behavior. Consider a superposition of two coherent states

| ψ = c 0 | α 0 + c 1 | α 1 {\displaystyle |\psi \rangle =c_{0}|\alpha _{0}\rangle +c_{1}|\alpha _{1}\rangle }

where c0 , c1 are constants subject to the normalizing constraint

1 = | c 0 | 2 + | c 1 | 2 + 2 e ( | α 0 | 2 + | α 1 | 2 ) / 2 Re ( c 0 c 1 e α 0 α 1 ) . {\displaystyle 1=|c_{0}|^{2}+|c_{1}|^{2}+2e^{-(|\alpha _{0}|^{2}+|\alpha _{1}|^{2})/2}\operatorname {Re} \left(c_{0}^{*}c_{1}e^{\alpha _{0}^{*}\alpha _{1}}\right).}

Note that this is quite different from a qubit because | α 0 {\displaystyle |\alpha _{0}\rangle } and | α 1 {\displaystyle |\alpha _{1}\rangle } are not orthogonal. As it is straightforward to calculate α | ρ ^ | α = α | ψ ψ | α {\displaystyle \langle -\alpha |{\hat {\rho }}|\alpha \rangle =\langle -\alpha |\psi \rangle \langle \psi |\alpha \rangle } , we can use the Mehta formula above to compute P,

P ( α ) = | c 0 | 2 δ 2 ( α α 0 ) + | c 1 | 2 δ 2 ( α α 1 ) + 2 c 0 c 1 e | α | 2 1 2 | α 0 | 2 1 2 | α 1 | 2 e ( α 1 α 0 ) / ( 2 α α 0 α 1 ) e ( α 0 α 1 ) / ( 2 α α 0 α 1 ) δ 2 ( 2 α α 0 α 1 ) + 2 c 0 c 1 e | α | 2 1 2 | α 0 | 2 1 2 | α 1 | 2 e ( α 0 α 1 ) / ( 2 α α 0 α 1 ) e ( α 1 α 0 ) / ( 2 α α 0 α 1 ) δ 2 ( 2 α α 0 α 1 ) . {\displaystyle {\begin{aligned}P(\alpha )={}&|c_{0}|^{2}\delta ^{2}(\alpha -\alpha _{0})+|c_{1}|^{2}\delta ^{2}(\alpha -\alpha _{1})\\&{}+2c_{0}^{*}c_{1}e^{|\alpha |^{2}-{\frac {1}{2}}|\alpha _{0}|^{2}-{\frac {1}{2}}|\alpha _{1}|^{2}}e^{(\alpha _{1}^{*}-\alpha _{0}^{*})\cdot \partial /\partial (2\alpha ^{*}-\alpha _{0}^{*}-\alpha _{1}^{*})}e^{(\alpha _{0}-\alpha _{1})\cdot \partial /\partial (2\alpha -\alpha _{0}-\alpha _{1})}\cdot \delta ^{2}(2\alpha -\alpha _{0}-\alpha _{1})\\&{}+2c_{0}c_{1}^{*}e^{|\alpha |^{2}-{\frac {1}{2}}|\alpha _{0}|^{2}-{\frac {1}{2}}|\alpha _{1}|^{2}}e^{(\alpha _{0}^{*}-\alpha _{1}^{*})\cdot \partial /\partial (2\alpha ^{*}-\alpha _{0}^{*}-\alpha _{1}^{*})}e^{(\alpha _{1}-\alpha _{0})\cdot \partial /\partial (2\alpha -\alpha _{0}-\alpha _{1})}\cdot \delta ^{2}(2\alpha -\alpha _{0}-\alpha _{1}).\end{aligned}}}

Despite having infinitely many derivatives of delta functions, P 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 P, the two expectation values match:

ψ | n ^ | ψ = P ( α ) | α | 2 d 2 α = | c 0 α 0 | 2 + | c 1 α 1 | 2 + 2 e ( | α 0 | 2 + | α 1 | 2 ) / 2 Re ( c 0 c 1 α 0 α 1 e α 0 α 1 ) . {\displaystyle {\begin{aligned}\langle \psi |{\hat {n}}|\psi \rangle &=\int P(\alpha )|\alpha |^{2}\,d^{2}\alpha \\&=|c_{0}\alpha _{0}|^{2}+|c_{1}\alpha _{1}|^{2}+2e^{-(|\alpha _{0}|^{2}+|\alpha _{1}|^{2})/2}\operatorname {Re} \left(c_{0}^{*}c_{1}\alpha _{0}^{*}\alpha _{1}e^{\alpha _{0}^{*}\alpha _{1}}\right).\end{aligned}}}

See also

References

  1. L. Cohen (1966). "Generalized phase-space distribution functions". J. Math. Phys. 7 (5): 781–786. Bibcode:1966JMP.....7..781C. doi:10.1063/1.1931206.
  2. L. Cohen (1976). "Quantization problem and variational principle in the phase space formulation of quantum mechanics". J. Math. Phys. 17 (10): 1863–1866. Bibcode:1976JMP....17.1863C. doi:10.1063/1.522807.
  3. ^ Schleich, Wolfgang P. (2001-02-09). Quantum Optics in Phase Space (1 ed.). Wiley. doi:10.1002/3527602976. ISBN 978-3-527-29435-0.
  4. ^ E. C. G. Sudarshan (1963). "Equivalence of semiclassical and quantum mechanical descriptions of statistical light beams". Phys. Rev. Lett. 10 (7): 277–279. Bibcode:1963PhRvL..10..277S. doi:10.1103/PhysRevLett.10.277.
  5. R. J. Glauber (1963). "Coherent and incoherent states of the radiation field". Phys. Rev. 131 (6): 2766–2788. Bibcode:1963PhRv..131.2766G. doi:10.1103/PhysRev.131.2766.
  6. It was the subject of a controversy when Glauber was awarded a share of the 2005 Nobel Prize in Physics for his work in this field and George Sudarshan's contribution was not recognized, cf. Zhou, Lulu (2005-12-06). "Scientists Question Nobel". The Harvard Crimson. Retrieved 2016-04-28.. Sudarshan's paper was received at Physical Review Letters on March 1, 1963, and published on April 1, 1963, while Glauber's paper was received at Physical Review on April 29, 1963, and published on September 15, 1963.
  7. C. L. Mehta; E. C. G. Sudarshan (1965). "Relation between quantum and semiclassical description of optical coherence". Phys. Rev. 138 (1B): B274–B280. Bibcode:1965PhRv..138..274M. doi:10.1103/PhysRev.138.B274.
  8. C. L. Mehta (1967). "Diagonal coherent-state representation of quantum operators". Phys. Rev. Lett. 18 (18): 752–754. Bibcode:1967PhRvL..18..752M. doi:10.1103/PhysRevLett.18.752.
  9. Mandel & Wolf 1995, p. 541
  10. Gerry, Christopher; Knight, Peter (2004). Introductory Quantum Optics. Cambridge: Cambridge University Press. doi:10.1017/cbo9780511791239. ISBN 978-0-521-52735-4.

Bibliography

Mandel, L.; Wolf, E. (1995), Optical Coherence and Quantum Optics, Cambridge UK: Cambridge University Press, ISBN 0-521-41711-2

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