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Switching Quantum Reference Frames for Quantum Measurement

Jianhao M. Yang

2020Quantum22 citationsDOIOpen Access PDF

Abstract

Physical observation is made relative to a reference frame. A reference frame is essentially a quantum system given the universal validity of quantum mechanics. Thus, a quantum system must be described relative to a quantum reference frame (QRF). Further requirements on QRF include using only relational observables and not assuming the existence of external reference frame. To address these requirements, two approaches are proposed in the literature. The first one is an operational approach (F. Giacomini, et al, Nat. Comm. 10:494, 2019) which focuses on the quantization of transformation between QRFs. The second approach attempts to derive the quantum transformation between QRFs from first principles (A. Vanrietvelde, et al,<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML"><mml:mrow class="MJX-TeXAtom-ORD"><mml:mtext class="MJX-tex-mathit" mathvariant="italic">Quantum</mml:mtext></mml:mrow></mml:math>4:225, 2020). Such first principle approach describes physical systems as symmetry induced constrained Hamiltonian systems. The Dirac quantization of such systems before removing redundancy is interpreted as perspective-neutral description. Then, a systematic redundancy reduction procedure is introduced to derive description from perspective of a QRF. The first principle approach recovers some of the results from the operational approach, but not yet include an important part of a quantum theory - the measurement theory. This paper is intended to bridge the gap. We show that the von Neumann quantum measurement theory can be embedded into the perspective-neutral framework. This allows us to successfully recover the results found in the operational approach, with the advantage that the transformation operator can be derived from the first principle. In addition, the formulation presented here reveals several interesting conceptual insights. For instance, the projection operation in measurement needs to be performed after redundancy reduction, and the projection operator must be transformed accordingly when switching QRFs. These results represent one step forward in understanding how quantum measurement should be formulated when the reference frame is also a quantum system.

Topics & Concepts

Quantum operationQuantumReference frameVon Neumann architectureQuantization (signal processing)Redundancy (engineering)Quantum processQuantum systemOpen quantum systemMathematicsQuantum stateFrame of referenceComputer scienceQuantum informationQuantum algorithmQuantum error correctionObservableTheoretical physicsQuantum networkTopology (electrical circuits)Quantum entanglementTransformation (genetics)Quantum technologyTheoretical computer scienceSecond quantizationQuantum capacityStatistical physicsCanonical quantizationOperator (biology)Quantum information scienceHamiltonian (control theory)Quantum Mechanics and ApplicationsQuantum Information and CryptographyQuantum Computing Algorithms and Architecture
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