Related papers: Heisenberg-Limited Waveform Estimation with Solid-State Spins in Diamond

Heisenberg-Limited Waveform Estimation with Solid-State Spins in Diamond

URL: http://arxiv.org/abs/2105.06037v1
Date: Thu, 13 May 2021 01:52:18 GMT
Title: Heisenberg-Limited Waveform Estimation with Solid-State Spins in Diamond
Authors: Yang Dong, Ze-Hao Wang, Hao-Bin Lin, Shao-Chun Zhang, Yu Zheng, Xiang-Dong Chen, Wei Zhu, Guan-Zhong Wang, Guang-Can Guo, Fang-Wen Sun
Abstract summary: Heisenberg limit in arbitrary waveform estimation is quite different with parameter estimation. It is still a non-trivial challenge to generate a large number of exotic quantum entangled states to achieve this quantum limit. This work provides an essential step towards realizing quantum-enhanced structure recognition in a continuous space and time.
Score: 15.419555338671772
License: http://creativecommons.org/licenses/by/4.0/
Abstract: The newly established Heisenberg limit in arbitrary waveform estimation is quite different with parameter estimation and shows a unique characteristic of a future quantum version of oscilloscope. However, it is still a non-trivial challenge to generate a large number of exotic quantum entangled states to achieve this quantum limit. Here, by employing the time-domain quantum difference detection method, we demonstrate Heisenberg-limited waveform quantum estimation with diamond spins under ambient condition in the experiment. Periodic dynamical decoupling is applied to enhance both the dynamic range and sensitivity by one order of magnitude. Using this quantum-enhanced estimation scheme, the estimation error of an unknown waveform is reduced by more than $5$ dB below the standard quantum limit with $N\sim{\text{2}} \times {\text{1}}{{\text{0}}^3}$ resources, where more than ${1 \times {\text{1}}{{\text{0}}^5}}$ resources would be required to achieve a similar error level using classical detection. This work provides an essential step towards realizing quantum-enhanced structure recognition in a continuous space and time.

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