Quantum-enhanced tomography of unitary processes

Zhou, Xiaoqi; Cable, Hugo; Whittaker, Rebecca; Shadbolt, Peter; O’Brien, Jeremy L; Matthews, Jonathan C. F.

doi:10.1364/optica.2.000510

Cited by 26 publications

(41 citation statements)

References 47 publications

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“…Indeed, the capability of obtaining quantum-enhanced performances in the multiparameter case is particularly relevant [9], since a large variety of estimation problems involve more than a single physical quantity. Notable examples are phase imaging [10][11][12], measurements on biological systems [13,14], magnetic field imaging [15], gravitational waves parameters estimation [16,17], sensing technologies [18,19], quantum sensing networks [20], quantum process tomography [21][22][23][24] and state estimation [25].…”

Section: Introductionmentioning

confidence: 99%

“…In the last few years, several theoretical investigations on multiparameter estimation have been reported [9,31,[34][35][36][37][38][39], while experimental tests are surprisingly few. These include the simultaneous estimation of phase and its diffusion noise [40][41][42], phase and quality of the probe state [43], the discrimination of an actual signal from parasitic interference [44], and quantum-enhanced tomography of an unknown unitary process by multiphoton states [21].…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Experimental multiphase estimation on a chip

Polino¹,

Riva²,

Valeri³

et al. 2019

Optica

116

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Multiparameter estimation is a general problem that aims at measuring unknown physical quantities, obtaining high precision in the process. In this context, the adoption of quantum resources promises a substantial boost in the achievable performances with respect to the classical case. However, several open problems remain to be addressed in the multiparameter scenario. A crucial requirement is the identification of suitable platforms to develop and experimentally test novel efficient methodologies that can be employed in this general framework. We report the experimental implementation of a reconfigurable integrated multimode interferometer designed for the simultaneous estimation of two optical phases. We verify the high-fidelity operation of the implemented device, and demonstrate quantum-enhanced performances in two-phase estimation with respect to the best classical case, post-selected to the number of detected coincidences. This device can be employed to test general adaptive multiphase protocols due to its high reconfigurability level, and represents a powerful platform to investigate the multiparameter estimation scenario.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Experimental multiphase estimation on a chip

Polino¹,

Riva²,

Valeri³

et al. 2019

Optica

116

View full text Add to dashboard Cite

show abstract

“…N00N states are maximally sensitive to small Uð1Þ phase shifts [5], but they are fragile. Other parameters might be best detected or estimated by a different optimal state [6,7], and for estimating even a simple three-parameter SUð2Þ process, the optimal state is unknown [8]. At the opposite extreme of metrology is quantum process tomography (QPT) [9,10].…”

Section: Introductionmentioning

confidence: 99%

Optimizing the Choice of Spin-Squeezed States for Detecting and Characterizing Quantum Processes

et al. 2014

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Quantum metrology uses quantum states with no classical counterpart to measure a physical quantity with extraordinary sensitivity or precision. Most such schemes characterize a dynamical process by probing it with a specially designed quantum state. The success of such a scheme usually relies on the process belonging to a particular one-parameter family. If this assumption is violated, or if the goal is to measure more than one parameter, a different quantum state may perform better. In the most extreme case, we know nothing about the process and wish to learn everything. This requires quantum process tomography, which demands an informationally complete set of probe states. It is very convenient if this set is group covarianti.e., each element is generated by applying an element of the quantum system's natural symmetry group to a single fixed fiducial state. In this paper, we consider metrology with 2-photon ("biphoton") states and report experimental studies of different states' sensitivity to small, unknown collective SUð2Þ rotations ["SUð2Þ jitter"]. Maximally entangled N00N states are the most sensitive detectors of such a rotation, yet they are also among the worst at fully characterizing an a priori unknown process. We identify (and confirm experimentally) the best SUð2Þ-covariant set for process tomography; these states are all less entangled than the N00N state, and are characterized by the fact that they form a 2-design.

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“…We are then left with the single mode final state y ñ | f . Recent progress in PNRD has made detections of larger numbers of photons possible, and transition edge sensors can now resolve at least four photons to a reasonable efficiency [8,41], whereas simpler detectors can reliably measure one or two photons [42][43][44]. The heralding number measurements we include in the toolbox are therefore á | 1 , á | 2 , á | 3 and á | 4 .…”

Section: A Quantum State Engineering Algorithmmentioning

confidence: 99%

A search algorithm for quantum state engineering and metrology

Knott

2016

New J. Phys.

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In this paper we present a search algorithm that finds useful optical quantum states which can be created with current technology. We apply the algorithm to the field of quantum metrology with the goal of finding states that can measure a phase shift to a high precision. Our algorithm efficiently produces a number of novel solutions: we find experimentally ready schemes to produce states that show significant improvements over the state-of-the-art, and can measure with a precision that beats the shot noise limit by over a factor of 4. Furthermore, these states demonstrate a robustness to moderate/high photon losses, and we present a conceptually simple measurement scheme that saturates the Cramér-Rao bound.

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Quantum-enhanced tomography of unitary processes

Cited by 26 publications

References 47 publications

Experimental multiphase estimation on a chip

Experimental multiphase estimation on a chip

Optimizing the Choice of Spin-Squeezed States for Detecting and Characterizing Quantum Processes

A search algorithm for quantum state engineering and metrology

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