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Saturating the Fuchs-van de Graaf inequality

Quantum Computing Asked on March 29, 2021

It is well-known that one side of the Fuchs-van de Graaf inequality is saturated for pure states, i.e. $F(rho,sigma)^2 = 1-d(rho,sigma)^2$ when $rho$ and $sigma$ are pure (here we are using the definition $F(rho, sigma) := |sqrt{rho}sqrt{sigma}|_1$ for fidelity). However, are there other situations where it is known that this equality holds? How far has this been characterized?

As a starting point, I am aware that when the states are qubits, it can be shown that $F(rho,sigma)^2 = 1-d(rho,sigma)^2$ holds if and only if the states have the same eigenvalues. (This is not too difficult to prove using specialized qubit expressions for the fidelity, but as far as I am aware, it does not seem to be well-known.) The "have the same eigenvalues" condition does not generalize even to qutrits, however, and hence it may perhaps not be the best approach to characterizing the conditions.

One Answer

This is not a saturation of the the Fuchs-van de Graaf upper bound, $F(rho,sigma)^2 = 1-d(rho,sigma)^2$, but rather the lower bound, $1 - sqrt{F(rho,sigma)} leq d(rho,sigma)$ (see, for example, here).

Consider, $rho = | psi rangle langle psi |$, a pure state and $sigma = frac{mathbb{I}}{d}$ is the maximally mixed state (for a $d$-dimensional Hilbert space). Then, the fidelity reduces to $F(| psi rangle langle psi | , frac{mathbb{I}}{d}) = langle psi | frac{mathbb{I}}{d} | psi rangle = frac{1}{d}$ (see, for example, Wikipedia).

And the trace norm distance is $leftVert | psi rangle langle psi | - frac{mathbb{I}}{d} rightVert_{1} = left( 1-frac{1}{d} right) + frac{d-1}{d} = 2(1-frac{1}{d})$. Therefore, using the normalized trace norm, $d(rho, sigma) equiv frac{1}{2} leftVert rho - sigma rightVert_{1}$, we have, $1 - F(rho,sigma) = d(rho,sigma)$

Answered by keisuke.akira on March 29, 2021

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