Precision measurement for open systems by non-hermitian linear response
- URL: http://arxiv.org/abs/2406.11287v1
- Date: Mon, 17 Jun 2024 07:51:02 GMT
- Title: Precision measurement for open systems by non-hermitian linear response
- Authors: Peng Xu, Gang Chen,
- Abstract summary: We show that the lower bound of estimated accuracy for a dissipative parameter non-unitarily encoded in open systems has been obtained.
This lower bound can guide us to find the optimal initial states and detection operators.
- Score: 9.087477434347218
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: The lower bound of estimated accuracy for a parameter unitarily encoded in closed systems has been obtained, and both optimal initial states and detection operators can be designed guided by the lower bound. In this letter, we demonstrate that the lower bound of estimated accuracy for a dissipative parameter non-unitarily encoded in open systems based on the non-hermitian linear response theory. This lower bound is related to the correlation of the encoding dissipative operator for open systems in contrast to the fluctuation of the encoding operator for closed systems. We also explicitly calculate the estimated accuracy for dissipative parameters corresponding to three different kinds of non-unitarily encoding processes, including particle loss, relaxation, and dephasing, which further confirm this lower bound. We finally compare the lower bound with the quantum Fisher information obtained by tomography, and we find they are consistent under suitable initial states and detection operators. This lower bound can guide us to find the optimal initial states and detection operators to significantly simplify the measurement process.
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