Quantum estimation via sequential measurements

Burgarth, Daniel; Giovannetti, Vittorio; N., Kato, Airi; Yuasa, Kazuya

doi:10.1088/1367-2630/17/11/113055

Cited by 27 publications

(31 citation statements)

References 47 publications

(130 reference statements)

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“…In the next section we shall study the behavior of (15) and (18) for fixed choices of the POVM operators M s and for fixed values of the number of the iterations n. In particular, we shall focus on the functional dependence of these quantities with respect to the input state ρ 0 of the probe.…”

Section: The Modelmentioning

confidence: 99%

“…which reads as in (24) ]. Replacing (22) into (15), and (25) into (18) we can now study the FI of the two procedures for different choices of the POVM parameter ϕ and for different values of the iterations n. In particular in the following subsections we shall focus on the dependence upon the input state ρ 0 of the probe Q. For the sake of simplicity and without loss of generality, the times t (or τ ) will be parametrized in units of the coupling constant γ, and the bath temperature T in units of the qubit energy gap Ω/k B .…”

Section: θ(T) := Tr[θρ(t)] = Tr[θementioning

confidence: 99%

“…In particular, the arbitrary initialization of independent probing systems at the beginning of the estimation procedure, or of a single probe at disposal after each measurement process, might encounter some obstructions, due to fundamental or practical reasons. One way to circumvent such difficulty is to rely on sequential measurement schemes (SMSs) [15][16][17][18], where repeated consecutive measurements are performed on a single probe while it is still in interaction with the bath without reinitializing it. The performance of SMS will be therefore compared with the IID protocol in different specific situations, taking the Fisher informations (FIs) [19][20][21][22][23] as the figure of merit for the corresponding temperature estimation accuracies.…”

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confidence: 99%

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Estimating temperature via sequential measurements

2017

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We study the efficiency of estimation procedures where the temperature of an external bath is indirectly recovered by monitoring the transformations induced on a probing system that is put in thermal contact with the bath. In particular we compare the performances of sequential measurement schemes where the probe is initialized only once and measured repeatedly during its interaction with the bath, with those of measure & re-prepare approaches where instead, after each interaction-and-measurement stage, the probe is reinitialized into the same fiduciary state. From our analysis it is revealed that the sequential approach, while being in general not capable of providing the best accuracy achievable, is nonetheless more versatile with respect to the choice of the initial state of the probe, yielding on average smaller indetermination levels.

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Section: The Modelmentioning

confidence: 99%

Section: θ(T) := Tr[θρ(t)] = Tr[θementioning

confidence: 99%

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Estimating temperature via sequential measurements

2017

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“…by preparing an initially entangled N-ancilla state [1,2]. Alternatively, one may perform N sequential measurements on the same ancilla [19][20][21][22], in such a way that the outcomes are correlated. Specifically in the context of thermometry, this method would generally not improve the accuracy of temperature estimation [21], but this could in principle change using adaptive schemes [22].…”

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Collisional Quantum Thermometry

et al. 2019

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We introduce a general framework for thermometry based on collisional models, where ancillas probe the temperature of the environment through an intermediary system. This allows for the generation of correlated ancillas even if they are initially independent. Using tools from parameter estimation theory, we show through a minimal qubit model that individual ancillas can already outperform the thermal Cramer-Rao bound. In addition, due to the steady-state nature of our model, when measured collectively the ancillas always exhibit superlinear scalings of the Fisher information. This means that even collective measurements on pairs of ancillas will already lead to an advantage. As we find in our qubit model, such a feature may be particularly valuable for weak system-ancilla interactions. Our approach sets forth the notion of metrology in a sequential interactions setting, and may inspire further advances in quantum thermometry.

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“…However, even with the rapid progress in the coherent manipulation and quantum-state tomography of several quantum systems, such as photons [6,7], electron spins [8][9][10], atomic qubits [11], superconducting circuits [12,13], and mechanical resonators [14,15], many quantum systems still remain difficult to access for a direct observation of their state, systems we will refer to as dark. In order to circumvent the requirement of such a direct access, a promising technique is to employ an auxiliary quantum system as a measurement probe, on which measurements as well as coherent manipulations can be performed [16][17][18][19][20][21][22][23]. Interferometry [24] based on such a measurement probe allows us to extract information on a target system [25][26][27][28][29][30].…”

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Pulsed Quantum-State Reconstruction of Dark Systems

et al. 2019

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We propose a novel strategy to reconstruct the quantum state of dark systems, i.e., degrees of freedom that are not directly accessible for measurement or control. Our scheme relies on the quantum control of a two-level probe that exerts a state-dependent potential on the dark system. Using a sequence of control pulses applied to the probe makes it possible to tailor the information one can obtain and, for example, allows us to reconstruct the density operator of a dark spin as well as the Wigner characteristic function of a harmonic oscillator. Because of the symmetry of the applied pulse sequence, this scheme is robust against slow noise on the probe. The proof-of-principle experiments are readily feasible in solid-state spins and trapped ions.Introduction.-The measurement of the quantum state of a system is a prerequisite ingredient in most modern quantum experiments, ranging from fundamental tests of quantum mechanics [1, 2] to various quantuminformation-processing tasks [3][4][5]. However, even with the rapid progress in the coherent manipulation and quantum-state tomography of several quantum systems, such as photons [6,7], electron spins [8-10], atomic qubits [11], superconducting circuits [12,13], and mechanical resonators [14,15], many quantum systems still remain difficult to access for a direct observation of their state, systems we will refer to as dark. In order to circumvent the requirement of such a direct access, a promising technique is to employ an auxiliary quantum system as a measurement probe, on which measurements as well as coherent manipulations can be performed [16][17][18][19][20][21][22][23]. Interferometry [24] based on such a measurement probe allows us to extract information on a target system [25][26][27][28][29][30]. Nevertheless, it still remains a key challenge to achieve a full quantum-state tomography of dark systems without requiring any direct control.

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Quantum estimation via sequential measurements

Cited by 27 publications

References 47 publications

Estimating temperature via sequential measurements

Estimating temperature via sequential measurements

Collisional Quantum Thermometry

Pulsed Quantum-State Reconstruction of Dark Systems

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