Fidelity of quantum states

Some authors use an alternative definition ${\displaystyle F':={\sqrt {F}}}$ and call this quantity fidelity.[4] The definition of ${\displaystyle F}$ however is more common.[5][6][7] To avoid confusion, ${\displaystyle F'}$ could be called “square root fidelity”. In any case it is advisable to clarify the adopted definition whenever the fidelity is employed.

Direct calculation shows that the fidelity is preserved by unitary evolution, i.e.

${\displaystyle \;F(\rho ,\sigma )=F(U\rho \;U^{*},U\sigma U^{*})}$

for any unitary operator ${\displaystyle U}$.

We saw that for two pure states, their fidelity coincides with the overlap. Uhlmann's theorem[8] generalizes this statement to mixed states, in terms of their purifications:

Theorem Let ρ and σ be density matrices acting on Cⁿ. Let ρ^½ be the unique positive square root of ρ and

$${\displaystyle |\psi _{\rho }\rangle =\sum _{i=1}^{n}(\rho ^{{1}/{2}}|e_{i}\rangle )\otimes |e_{i}\rangle \in \mathbb {C} ^{n}\otimes \mathbb {C} ^{n}}$$

be a purification of ρ (therefore ${\displaystyle \textstyle \{|e_{i}\rangle \}}$ is an orthonormal basis), then the following equality holds:

${\displaystyle F(\rho ,\sigma )=\max _{|\psi _{\sigma }\rangle }|\langle \psi _{\rho }|\psi _{\sigma }\rangle |^{2}}$

where ${\displaystyle |\psi _{\sigma }\rangle }$ is a purification of σ. Therefore, in general, the fidelity is the maximum overlap between purifications.

A simple proof can be sketched as follows. Let ${\displaystyle \textstyle |\Omega \rangle }$ denote the vector

${\displaystyle |\Omega \rangle =\sum _{i=1}^{n}|e_{i}\rangle \otimes |e_{i}\rangle }$

and σ^½ be the unique positive square root of σ. We see that, due to the unitary freedom in square root factorizations and choosing orthonormal bases, an arbitrary purification of σ is of the form

${\displaystyle |\psi _{\sigma }\rangle =(\sigma ^{{1}/{2}}V_{1}\otimes V_{2})|\Omega \rangle }$

where V_i's are unitary operators. Now we directly calculate

${\displaystyle |\langle \psi _{\rho }|\psi _{\sigma }\rangle |^{2}=|\langle \Omega |(\rho ^{{1}/{2}}\otimes I)(\sigma ^{{1}/{2}}V_{1}\otimes V_{2})|\Omega \rangle |^{2}=|\operatorname {tr} (\rho ^{{1}/{2}}\sigma ^{{1}/{2}}V_{1}V_{2}^{T})|^{2}.}$

But in general, for any square matrix A and unitary U, it is true that |tr(AU)| ≤ tr((A^*A)^½). Furthermore, equality is achieved if U^* is the unitary operator in the polar decomposition of A. From this follows directly Uhlmann's theorem.

We will here provide an alternative, explicit way to prove Uhlmann's theorem.

Let ${\displaystyle |\psi _{\rho }\rangle }$ and ${\displaystyle |\psi _{\sigma }\rangle }$ be purifications of ${\displaystyle \rho }$ and ${\displaystyle \sigma }$, respectively. To start, let us show that ${\displaystyle |\langle \psi _{\rho }|\psi _{\sigma }\rangle |\leq \operatorname {tr} |{\sqrt {\rho }}{\sqrt {\sigma }}|}$.

The general form of the purifications of the states is:

$${\displaystyle {\begin{aligned}|\psi _{\rho }\rangle &=\sum _{k}{\sqrt {\lambda _{k}}}|\lambda _{k}\rangle \otimes |u_{k}\rangle ,\\|\psi _{\sigma }\rangle &=\sum _{k}{\sqrt {\mu _{k}}}|\mu _{k}\rangle \otimes |v_{k}\rangle ,\end{aligned}}}$$

were ${\displaystyle |\lambda _{k}\rangle ,|\mu _{k}\rangle }$ are the eigenvectors of ${\displaystyle \rho ,\ \sigma }$, and ${\displaystyle \{u_{k}\}_{k},\{v_{k}\}_{k}}$ are arbitrary orthonormal bases. The overlap between the purifications is

$${\displaystyle \langle \psi _{\rho }|\psi _{\sigma }\rangle =\sum _{jk}{\sqrt {\lambda _{j}\mu _{k}}}\langle \lambda _{j}|\mu _{k}\rangle \,\langle u_{j}|v_{k}\rangle =\operatorname {tr} \left({\sqrt {\rho }}{\sqrt {\sigma }}U\right),}$$

where the unitary matrix ${\displaystyle U}$ is defined as

$${\displaystyle U=\left(\sum _{k}|\mu _{k}\rangle \!\langle u_{k}|\right)\,\left(\sum _{j}|v_{j}\rangle \!\langle \lambda _{j}|\right).}$$

The conclusion is now reached via using the inequality ${\displaystyle |\operatorname {tr} (AU)|\leq \operatorname {tr} ({\sqrt {A^{\dagger }A}})\equiv \operatorname {tr} |A|}$:

$${\displaystyle |\langle \psi _{\rho }|\psi _{\sigma }\rangle |=|\operatorname {tr} ({\sqrt {\rho }}{\sqrt {\sigma }}U)|\leq \operatorname {tr} |{\sqrt {\rho }}{\sqrt {\sigma }}|.}$$

Note that this inequality is the triangle inequality applied to the singular values of the matrix. Indeed, for a generic matrix ${\displaystyle A\equiv \sum _{j}s_{j}(A)|a_{j}\rangle \!\langle b_{j}|}$and unitary ${\displaystyle U=\sum _{j}|b_{j}\rangle \!\langle w_{j}|}$, we have

$${\displaystyle {\begin{aligned}|\operatorname {tr} (AU)|&=\left|\operatorname {tr} \left(\sum _{j}s_{j}(A)|a_{j}\rangle \!\langle b_{j}|\,\,\sum _{k}|b_{k}\rangle \!\langle w_{k}|\right)\right|\\&=\left|\sum _{j}s_{j}(A)\langle w_{j}|a_{j}\rangle \right|\\&\leq \sum _{j}s_{j}(A)\,|\langle w_{j}|a_{j}\rangle |\\&\leq \sum _{j}s_{j}(A)\\&=\operatorname {tr} |A|,\end{aligned}}}$$

where ${\displaystyle s_{j}(A)\geq 0}$ are the (always real and non-negative) singular values of ${\displaystyle A}$, as in the singular value decomposition. The inequality is saturated and becomes an equality when ${\displaystyle \langle w_{j}|a_{j}\rangle =1}$, that is, when ${\displaystyle U=\sum _{k}|b_{k}\rangle \!\langle a_{k}|,}$ and thus ${\displaystyle AU={\sqrt {AA^{\dagger }}}\equiv |A|}$. The above shows that ${\displaystyle |\langle \psi _{\rho }|\psi _{\sigma }\rangle |=\operatorname {tr} |{\sqrt {\rho }}{\sqrt {\sigma }}|}$ when the purifications ${\displaystyle |\psi _{\rho }\rangle }$ and ${\displaystyle |\psi _{\sigma }\rangle }$ are such that ${\displaystyle {\sqrt {\rho }}{\sqrt {\sigma }}U=|{\sqrt {\rho }}{\sqrt {\sigma }}|}$. Because this choice is possible regardless of the states, we can finally conclude that

$${\displaystyle \operatorname {tr} |{\sqrt {\rho }}{\sqrt {\sigma }}|=\max |\langle \psi _{\rho }|\psi _{\sigma }\rangle |.}$$

Some immediate consequences of Uhlmann's theorem are

• Fidelity is symmetric in its arguments, i.e. F (ρ,σ) = F (σ,ρ). Note that this is not obvious from the original definition.
• F (ρ,σ) lies in [0,1], by the Cauchy–Schwarz inequality.
• F (ρ,σ) = 1 if and only if ρ = σ, since Ψ_ρ = Ψ_σ implies ρ = σ.

So we can see that fidelity behaves almost like a metric. This can be formalized and made useful by defining

${\displaystyle \cos ^{2}\theta _{\rho \sigma }=F(\rho ,\sigma )\,}$

As the angle between the states ${\displaystyle \rho }$ and ${\displaystyle \sigma }$. It follows from the above properties that ${\displaystyle \theta _{\rho \sigma }}$ is non-negative, symmetric in its inputs, and is equal to zero if and only if ${\displaystyle \rho =\sigma }$. Furthermore, it can be proved that it obeys the triangle inequality,[4] so this angle is a metric on the state space: the Fubini–Study metric.[9]

Let ${\displaystyle \{E_{k}\}_{k}}$ be an arbitrary positive operator-valued measure (POVM); that is, a set of operators ${\displaystyle E_{k}}$ satisfying ${\displaystyle \sum _{k}E_{k}=I}$, ${\displaystyle E_{j}E_{k}=\delta _{jk}E_{j}}$, and ${\displaystyle E_{k}^{2}=E_{k}}$. Then, for any pair of states ${\displaystyle \rho }$ and ${\displaystyle \sigma }$, we have

$${\displaystyle {\sqrt {F(\rho ,\sigma )}}\leq \sum _{k}{\sqrt {\operatorname {tr} (E_{k}\rho )}}{\sqrt {\operatorname {tr} (E_{k}\sigma )}}\equiv \sum _{k}{\sqrt {p_{k}q_{k}}},}$$

where in the last step we denoted with ${\displaystyle p_{k},q_{k}}$ the probability distributions obtained by measuring ${\displaystyle \rho ,\ \sigma }$ with the POVM ${\displaystyle \{E_{k}\}_{k}}$.

This shows that the square root of the fidelity between two quantum states is upper bounded by the Bhattacharyya coefficient between the corresponding probability distributions in any possible POVM. Indeed, it is more generally true that

$${\displaystyle F(\rho ,\sigma )=\min _{\{E_{k}\}}F({\boldsymbol {p}},{\boldsymbol {q}}),}$$

where ${\displaystyle F({\boldsymbol {p}},{\boldsymbol {q}})\equiv \left(\sum _{k}{\sqrt {p_{k}q_{k}}}\right)^{2}}$, and the minimum is taken over all possible POVMs.

As was previously shown, the square root of the fidelity can be written as ${\displaystyle {\sqrt {F(\rho ,\sigma )}}=\operatorname {tr} |{\sqrt {\rho }}{\sqrt {\sigma }}|,}$which is equivalent to the existence of a unitary operator ${\displaystyle U}$ such that

$${\displaystyle {\sqrt {F(\rho ,\sigma )}}=\operatorname {tr} ({\sqrt {\rho }}{\sqrt {\sigma }}U).}$$

Remembering that ${\displaystyle \sum _{k}E_{k}=I}$ holds true for any POVM, we can then write

$${\displaystyle {\sqrt {F(\rho ,\sigma )}}=\operatorname {tr} ({\sqrt {\rho }}{\sqrt {\sigma }}U)=\sum _{k}\operatorname {tr} ({\sqrt {\rho }}E_{k}E_{k}{\sqrt {\sigma }}U)\leq \sum _{k}{\sqrt {\operatorname {tr} (E_{k}\rho )\operatorname {tr} (E_{k}\sigma )}},}$$

where in the last step we used Cauchy-Schwarz inequality as in ${\displaystyle |\operatorname {tr} (A^{\dagger }B)|^{2}\leq \operatorname {tr} (A^{\dagger }A)\operatorname {tr} (B^{\dagger }B)}$.

The fidelity between two states can be shown to never decrease when a non-selective quantum operation ${\displaystyle {\mathcal {E}}}$ is applied to the states:[10]

$${\displaystyle F({\mathcal {E}}(\rho ),{\mathcal {E}}(\sigma ))\geq F(\rho ,\sigma ),}$$

for any trace-preserving completely positive map ${\displaystyle {\mathcal {E}}}$.

We can define the trace distance between two matrices A and B in terms of the trace norm by

${\displaystyle D(A,B)={\frac {1}{2}}\|A-B\|_{\rm {tr}}\,.}$

When A and B are both density operators, this is a quantum generalization of the statistical distance. This is relevant because the trace distance provides upper and lower bounds on the fidelity as quantified by the Fuchs–van de Graaf inequalities,[11]

${\displaystyle 1-{\sqrt {F(\rho ,\sigma )}}\leq D(\rho ,\sigma )\leq {\sqrt {1-F(\rho ,\sigma )}}\,.}$

Often the trace distance is easier to calculate or bound than the fidelity, so these relationships are quite useful. In the case that at least one of the states is a pure state Ψ, the lower bound can be tightened.

${\displaystyle 1-F(\psi ,\rho )\leq D(\psi ,\rho )\,.}$