Machine-learning-assisted electron-spin readout of nitrogen-vacancy center in diamond

Qian, Peng; Lin, Xue; Zhou, Feifei; Ye, Runchuan; Ji, Yunlan; Chen, Bing; Xie, Guangjun; Xu, Nanyang

doi:10.1063/5.0038590

Cited by 24 publications

(11 citation statements)

References 36 publications

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“…In particular, the ML ideology was successfully applied in several experimental reports on photonic metamaterials: refs. [19,22,24,31,61,62]. One of the goals of this paper is to motivate experimental work in electromagnetic Mie sensing.…”

Section: Discussionmentioning

confidence: 99%

“…Those parameters can be, e.g., nanostructure dimension, [25,26,29] morphology [30] and shape, [23] or chiral nano-object design. [27][28][29] Nonetheless, there are notable works showing interest in performing classification tasks in nanophotonics, e.g., the optical recording of electron-spin states in diamond via single-photon collection, [31] strengthening readout in high-density data storage, [19] or the label-free identification of pathogenic bacteria [24] and cells. [32] The inverse problem can also be addressed through a mixed approach, e.g., when the physical dimensions of nano-objects are predicted by regression, while their material is labeled and classified.…”

Section: Introductionmentioning

confidence: 99%

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Mie Sensing with Neural Networks: Recognition of Nano‐Object Parameters, the Invisibility Point, and Restricted Models

Movsesyan

Besteiro

Wang

et al. 2021

Advcd Theory and Sims

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In this work, artificial neural networks (ANNs) are used to recognize nano-objects solely from the absorbance spectrum of a macroscopic sample. For this, ANNs with two recognition schemes are constructed. The first one is designed to recognize ensembles of dielectric scatterers. The second ANN model recognizes the dimensions of gold nanospheres in a mixture and the refractive index of a matrix. A challenge in the first scheme arises at and near the invisibility point, i.e., when the refractive index of nanoparticles is close to that of the medium. Of course, particle recognition in this regime faces fundamental physical limitations. However, such recognition near the invisibility point is possible, and this study reveals its unique properties. Interestingly, the recognition process for the refractive index in the vicinity of the invisibility point shows very small errors. In contrast, the errors for recognition of the radius grow strongly near this point. Another regime with limited recognition occurs when the extinction spectra are not unique and can correspond to different realizations of nanoparticle mixtures. The recognition schemes proposed and investigated herein can find their applications in sensing.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Mie Sensing with Neural Networks: Recognition of Nano‐Object Parameters, the Invisibility Point, and Restricted Models

Movsesyan

Besteiro

Wang

et al. 2021

Advcd Theory and Sims

View full text Add to dashboard Cite

show abstract

“…The training set contains Mj = 2 × 10 3 feature vectors at each grid point (on average) and during training we use a mini-batch size of 256 with 75 training epochs, which ensures the cost saturates the phase-averaged CRB Eq. (18). models Θ W until the phase-averaged CRB is saturated, and compare the mean (solid blue) and standard deviation (shaded gray region) to the MLE (dashed orange).…”

Section: Non-classical States Of Many Qubitsmentioning

confidence: 99%

“…Quantum parameter estimation is an active area of research, which has both fascinating implications for fundamental science and applications in state-of-the art quantum sensors [1,2]. Like many areas of quantum science, quantum parameter estimation can potentially benefit from the application of machine learning techniques [3,4,29], in particular adaptive Bayesian schemes [5][6][7][8][9][10][11][12][13][14], improved readout in noisy single-qubit magnetometers [15][16][17][18][19] and state preparation [20,21]. Although current efforts to improve the sensitivity and utility of quantum sensors is focused on the use of non-classical states [1], the development of sophisticated data analysis techniques to extract information encoded in complex quantum states is also an important aspect of this effort.…”

Section: Introductionmentioning

confidence: 99%

Frequentist Parameter Estimation with Supervised Learning

Nolan¹,

Pezzé²,

Smerzi³

2021

Preprint

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Recently there has been a great deal of interest surrounding the calibration of quantum sensors using machine learning techniques. In this work, we explore the use of regression to infer a machinelearned point estimate of an unknown parameter. Although the analysis is neccessarily frequentistrelying on repeated esitmates to build up statistics -we clarify that this machine-learned estimator converges to the Bayesian maximum a-posterori estimator (subject to some regularity conditions). When the number of training measurements are large, this is identical to the well-known maximumlikelihood estimator (MLE), and using this fact, we argue that the Cramér-Rao sensitivity bound applies to the mean-square error cost function and can therefore be used to select optimal model and training parameters. We show that the machine-learned estimator inherits the desirable asymptotic properties of the MLE, up to a limit imposed by the resolution of the training grid. Furthermore, we investigate the role of quantum noise the training process, and show that this noise imposes a fundamental limit on number of grid points. This manuscript paves the way for machine-learning to assist the calibration of quantum sensors, thereby allowing maximum-likelihood inference to play a more prominent role in the design and operation of the next generation of ultra-precise sensors.

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“…Machine learning is a group of methods that are well developed in computer science and has been applied in quantum control fields including Hamilto-nian learning [14], qubit readout [15][16][17][18][19] and experimental controls [20,21]. Recently, the deep learning model (DL) [22] is emerging as a powerful tool, which can deal with complicated problems with multiple layers of artificial neural network such as the many-body problem [23].…”

Section: Introductionmentioning

confidence: 99%

Feedforward Quantum Control and Coherence Protection of Single Electron Spin in Diamond using Deep Learning

Xu¹,

Zhou²,

Ye³

et al. 2022

Preprint

Self Cite

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Measurement-based realtime control is an important strategy in quantum information processing, which is applied in fields from qubit readout to error corrections. However, the time cost of quantum measurement inevitably induces a latency in the control process and limits its performance. Here we introduce the deep learning approach to relax this restriction by predicting and compensating the latency-induced control error. We experimentally implement feedforward quantum control of a single-spin system of nitrogen-vacancy (NV) center in diamond to protect the coherence of the electron spin. The new approach enhances the decoherence time as well as the the spectrum resolution of Ramsey interferometry about three times comparing with conventional scheme. This enables resolving optically indistinguishable NV centers from their magnetic spectrum with a frequency difference less than 20 kHz. A theoretical model is proposed to explain the improvement, where we show that the low-frequency magnetic noise is perfectly reduced. This scheme could be applied in general measurement schemes and extended to other quantum control systems. RESULTSNV center in diamond has been developed as a multi-function sensor for magnetic field [25][26][27][28][29][30], electric

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Machine-learning-assisted electron-spin readout of nitrogen-vacancy center in diamond

Cited by 24 publications

References 36 publications

Mie Sensing with Neural Networks: Recognition of Nano‐Object Parameters, the Invisibility Point, and Restricted Models

Mie Sensing with Neural Networks: Recognition of Nano‐Object Parameters, the Invisibility Point, and Restricted Models

Frequentist Parameter Estimation with Supervised Learning

Feedforward Quantum Control and Coherence Protection of Single Electron Spin in Diamond using Deep Learning

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