Precision and Privacy in Distributed Quantum Sensing: A Quantum Fisher Information Duality
This work provides a fundamental trade-off between precision and privacy in distributed quantum sensing, relevant for quantum metrology and secure sensing applications.
The paper establishes a quantum Fisher information duality for distributed quantum sensor networks, showing that Heisenberg-limited precision for one sensing direction forces zero precision for all orthogonal directions, which provides a condition for parameter privacy.
We establish a quantum Fisher information (QFI) duality for distributed quantum sensor networks with local phase encoding. For any $N$-qubit probe state, where $N$ denotes the number of sensors, $F_Q(\boldsymbol{w}^\top \boldsymbolθ) + F_Q(\boldsymbol{v}^\top \boldsymbolθ) \leq N$ for all unit orthogonal sensing directions $\boldsymbol{w}$ and $\boldsymbol{v}$, with equality for all equatorial states when $N=2$ and for Greenberger--Horne--Zeilinger (GHZ) states when $N\geq 2$. Heisenberg-limited precision for direction $\boldsymbol{w}$, $F_Q(\boldsymbol{w}^\top \boldsymbolθ)=N$, saturates the bound and simultaneously forces zero QFI for all other independent directions. This can be interpreted as the condition for parameter privacy in distributed quantum sensing: attaining Heisenberg-limited precision for the sensing target renders all alternative privacy-intrusive estimations impossible.