Arthur J. Parzygnat’s research while affiliated with Massachusetts Institute of Technology and other places

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Publications (35)


Quantum Mutual Information in Time
  • Preprint

October 2024

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6 Reads

James Fullwood

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Zhen Wu

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Arthur J. Parzygnat

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Vlatko Vedral

While the quantum mutual information is a fundamental measure of quantum information, it is only defined for spacelike-separated quantum systems. Such a limitation is not present in the theory of classical information, where the mutual information between two random variables is well-defined irrespective of whether or not the variables are separated in space or separated in time. Motivated by this disparity between the classical and quantum mutual information, we employ the pseudo-density matrix formalism to define a simple extension of quantum mutual information into the time domain. As in the spatial case, we show that such a notion of quantum mutual information in time serves as a natural measure of correlation between timelike-separated systems, while also highlighting ways in which quantum correlations distinguish between space and time. We also show how such quantum mutual information is time-symmetric with respect to quantum Bayesian inversion, and then we conclude by showing how mutual information in time yields a Holevo bound for the amount of classical information that may be extracted from sequential measurements on an ensemble of quantum states.


FIG. 5. The set of values for ϵ ∈ (0, 1), γ ∈ (0, 1), and z = r3 ∈ (0, 1) for which the Bayesian inverse of the map E given by (C24) and state ρ = 1 2 (12 + r3σ3) is a valid quantum channel.
Time-symmetric correlations for open quantum systems
  • Preprint
  • File available

July 2024

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12 Reads

Two-time expectation values of sequential measurements of dichotomic observables are known to be time symmetric for closed quantum systems. Namely, if a system evolves unitarily between sequential measurements of dichotomic observables OA\mathscr{O}_{A} followed by OB\mathscr{O}_{B}, then it necessarily follows that OA,OB=OB,OA\langle\mathscr{O}_{A}\,,\mathscr{O}_{B}\rangle=\langle\mathscr{O}_{B}\,,\mathscr{O}_{A}\rangle, where OA,OB\langle\mathscr{O}_{A}\,,\mathscr{O}_{B}\rangle is the two-time expectation value corresponding to the product of the measurement outcomes of OA\mathscr{O}_{A} followed by OB\mathscr{O}_{B}, and OB,OA\langle\mathscr{O}_{B}\,,\mathscr{O}_{A}\rangle is the two-time expectation value associated with the time reversal of the unitary dynamics, where a measurement of OB\mathscr{O}_{B} precedes a measurement of OA\mathscr{O}_{A}. In this work, we show that a quantum Bayes' rule implies a time symmetry for two-time expectation values associated with open quantum systems, which evolve according to a general quantum channel between measurements. Such results are in contrast with the view that processes associated with open quantum systems -- which may lose information to their environment -- are not reversible in any operational sense. We give an example of such time-symmetric correlations for the amplitude-damping channel, and we propose an experimental protocol for the potential verification of the theoretical predictions associated with our results.

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Operator representation of spatiotemporal quantum correlations

May 2024

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7 Reads

While quantum correlations between two spacelike-separated systems are fully encoded by the bipartite density operator associated with the joint system, we prove that there does not exist an operator representation for general quantum correlations across space and time. This is in stark contrast to the case of classical random variables, which make no distinction between spacelike and timelike correlations. Despite this, we show that in the restricted setting of spatiotemporal correlations between light-touch observables (i.e., observables with only one singular value), there exists a unique operator representation of such spatiotemporal correlations for arbitrary timelike-separated quantum systems. A special case of our result reproduces generalized Pauli observables and pseudo-density matrices, which have, up until now, only been defined for multi-qubit systems. In the case of qutrit systems, we use our results to illustrate an intriguing connection between light-touch observables and symmetric, informationally complete, positive operator-valued measures (SIC-POVMs).


Virtual Quantum Broadcasting

March 2024

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14 Reads

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8 Citations

Physical Review Letters

The quantum no-broadcasting theorem states that it is impossible to produce perfect copies of an arbitrary quantum state, even if the copies are allowed to be correlated. Here we show that, although quantum broadcasting cannot be achieved by any physical process, it can be achieved by a virtual process, described by a Hermitian-preserving trace-preserving map. This virtual process is canonical: it is the only map that broadcasts all quantum states, is covariant under unitary evolution, is invariant under permutations of the copies, and reduces to the classical broadcasting map when subjected to decoherence. We show that the optimal physical approximation to the canonical broadcasting map is the optimal universal quantum cloning, and we also show that virtual broadcasting can be achieved by a virtual measure-and-prepare protocol, where a virtual measurement is performed, and, depending on the outcomes, two copies of a virtual quantum state are generated. Finally, we use canonical virtual broadcasting to prove a uniqueness result for quantum states over time.


SVD entanglement entropy

December 2023

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103 Reads

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11 Citations

Journal of High Energy Physics

A bstract In this paper, we introduce a new quantity called SVD entanglement entropy. This is a generalization of entanglement entropy in that it depends on two different states, as in pre- and post-selection processes. This SVD entanglement entropy takes non-negative real values and is bounded by the logarithm of the Hilbert space dimensions. The SVD entanglement entropy can be interpreted as the average number of Bell pairs distillable from intermediates states. We observe that the SVD entanglement entropy gets enhanced when the two states are in the different quantum phases in an explicit example of the transverse-field Ising model. Moreover, we calculate the Rényi SVD entropy in various field theories and examine holographic calculations using the AdS/CFT correspondence.


Non-commutative disintegrations: Existence and uniqueness in finite dimensions

July 2023

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12 Reads

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7 Citations

Journal of Noncommutative Geometry

Motivated by advances in categorical probability, we introduce non-commutative almost everywhere (a.e.) equivalence and disintegrations in the setting of C^* -algebras. We show that C^* -algebras (resp. W^* -algebras) and a.e. equivalence classes of 2-positive (resp. positive) unital maps form a category. We prove that non-commutative disintegrations are a.e. unique whenever they exist. We provide an explicit characterization for when disintegrations exist in the setting of finite-dimensional C^* -algebras, and we give formulas for the associated disintegrations.


SVD Entanglement Entropy

July 2023

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74 Reads

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3 Citations

In this paper, we introduce a new quantity called SVD entanglement entropy. This is a generalization of entanglement entropy in that it depends on two different states, as in pre- and post-selection processes. This SVD entanglement entropy takes non-negative real values and is bounded by the logarithm of the Hilbert space dimensions. The SVD entanglement entropy can be interpreted as the average number of Bell pairs distillable from intermediates states. We observe that the SVD entanglement entropy gets enhanced when the two states are in the different quantum phases in an explicit example of the transverse-field Ising model. Moreover, we calculate the R{\'e}nyi SVD entropy in various field theories and examine holographic calculations using the AdS/CFT correspondence.


On dynamical measures of quantum information

June 2023

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32 Reads

In this work, we use the theory of quantum states over time to define an entropy S(ρ,E)S(\rho,\mathcal{E}) associated with quantum processes (ρ,E)(\rho,\mathcal{E}), where ρ\rho is a state and E\mathcal{E} is a quantum channel responsible for the dynamical evolution of ρ\rho. The entropy S(ρ,E)S(\rho,\mathcal{E}) is a generalization of the von Neumann entropy in the sense that S(ρ,id)=S(ρ)S(\rho,\mathrm{id})=S(\rho) (where id\mathrm{id} denotes the identity channel), and is a dynamical analogue of the quantum joint entropy for bipartite states. Such an entropy is then used to define dynamical formulations of the quantum conditional entropy and quantum mutual information, and we show such information measures satisfy many desirable properties, such as a quantum entropic Bayes' rule. We also use our entropy function to quantify the information loss/gain associated with the dynamical evolution of quantum systems, which enables us to formulate a precise notion of information conservation for quantum processes.


From Time-Reversal Symmetry to Quantum Bayes’ Rules

June 2023

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73 Reads

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36 Citations

PRX Quantum

Bayes’ rule, P(B|A)P(A)=P(A|B)P(B), is one of the simplest yet most profound, ubiquitous, and far-reaching results of classical probability theory, with applications in any field utilizing statistical inference. Many attempts have been made to extend this rule to quantum systems, the significance of which we are only beginning to understand. In this work, we develop a systematic framework for defining Bayes’ rule in the quantum setting, and we show that a vast majority of the proposed quantum Bayes’ rules appearing in the literature are all instances of our definition. Moreover, our Bayes’ rule is based upon a simple relationship between the notions of state over time and a time-reversal-symmetry map, both of which are introduced here.


Figure 1: The sets (not drawn to scale) and their inclusion structure depict four families of channels (the inclusion structure is not meant to include the states). The standard time-reversal symmetry is obtained by taking the Hilbert-Schmidt adjoint of a reversible channel, or, more generally, a bistochastic channel. The states (drawn schematically as matrices with shaded entries) are irrelevant for reversible channels, but are implicitly the uniform states for bistochastic channels. For classical channels equipped with arbitrary probability distributions, standard Bayesian inversion provides a form of time-reversal symmetry that goes beyond the Hilbert-Schmidt adjoint for bistochastic channels. Finally, the Petz recovery map allows an extension of Bayesian inversion to all quantum channels and arbitrary states. In brief, this paper isolates axioms for retrodiction and inferential time-reversal symmetry that are simultaneously satisfied by all of these classes of channels and states.
Axioms for retrodiction: achieving time-reversal symmetry with a prior

May 2023

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40 Reads

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24 Citations

Quantum

We propose a category-theoretic definition of retrodiction and use it to exhibit a time-reversal symmetry for all quantum channels. We do this by introducing retrodiction families and functors, which capture many intuitive properties that retrodiction should satisfy and are general enough to encompass both classical and quantum theories alike. Classical Bayesian inversion and all rotated and averaged Petz recovery maps define retrodiction families in our sense. However, averaged rotated Petz recovery maps, including the universal recovery map of Junge-Renner-Sutter-Wilde-Winter, do not define retrodiction functors, since they fail to satisfy some compositionality properties. Among all the examples we found of retrodiction families, the original Petz recovery map is the only one that defines a retrodiction functor. In addition, retrodiction functors exhibit an inferential time-reversal symmetry consistent with the standard formulation of quantum theory. The existence of such a retrodiction functor seems to be in stark contrast to the many no-go results on time-reversal symmetry for quantum channels. One of the main reasons is because such works defined time-reversal symmetry on the category of quantum channels alone, whereas we define it on the category of quantum channels and quantum states. This fact further illustrates the importance of a prior in time-reversal symmetry.


Citations (20)


... While a ⋆-product on 1-chains was referred to as a "QSOT function" in Refs. [13,23,24], we use the ⋆-product terminology to be more consistent with the notation E ⋆ ρ. ...

Reference:

Unique multipartite extension of quantum states over time
Virtual Quantum Broadcasting
  • Citing Article
  • March 2024

Physical Review Letters

... Generalizations of the entanglement entropy S ϕ E (of a state |ϕ⟩) of our primary interest in this work are pseudo-entropy denoted S ϕ|ψ P [11], and SVD entropy denoted S ϕ|ψ SVD [12]. Recall that entanglement entropy characterizes entanglement between two subsets of a Hilbert space; they are often taken to be associated to two subregions of the spatial domain on which a system under consideration is defined. ...

SVD entanglement entropy

Journal of High Energy Physics

... While spacelike quantum correlations are at the heart of many foundational aspects of quantum theory-such as quantum entanglement and the failure of local realism [2][3][4][5][6][7][8][9][10]-quantum correlations across space and time are much less understood [11][12][13][14][15][16][17][18][19][20][21][22][23][24][25][26][27]. For example, there is no well-established notion of entanglement for timelikeseparated systems [28][29][30][31][32][33][34][35][36][37][38][39]. ...

Non-commutative disintegrations: Existence and uniqueness in finite dimensions

Journal of Noncommutative Geometry

... review [1]). Apart from providing means to describe complex systems, other motivations to study various incarnations of entropy include their geometric interpretation via AdS/CFT correspondence [2][3][4][5], the potential to characterize topological properties of various systems [6,7] and topological field theories in particular, the capability to describe the process of post-selection [8,9], applications of these JHEP11(2024)103 ideas in condensed matter physics [10], etc. Generalizations of the entanglement entropy S ϕ E (of a state |ϕ⟩) of our primary interest in this work are pseudo-entropy denoted S ϕ|ψ P [11], and SVD entropy denoted S ϕ|ψ SVD [12]. Recall that entanglement entropy characterizes entanglement between two subsets of a Hilbert space; they are often taken to be associated to two subregions of the spatial domain on which a system under consideration is defined. ...

SVD Entanglement Entropy

... Causal structure inference is also being investigated in the more fundamental quantum level [8][9][10][11][12][13][14][15][16][17][18][19][20][21][22][23]. Causal inference via interventions, in particular resetting the state of the quantum system, have been considered [24][25][26][27][28][29][30][31][32]. ...

From Time-Reversal Symmetry to Quantum Bayes’ Rules

PRX Quantum

... While spacelike quantum correlations are at the heart of many foundational aspects of quantum theory-such as quantum entanglement and the failure of local realism [2][3][4][5][6][7][8][9][10]-quantum correlations across space and time are much less understood [11][12][13][14][15][16][17][18][19][20][21][22][23][24][25][26][27]. For example, there is no well-established notion of entanglement for timelikeseparated systems [28][29][30][31][32][33][34][35][36][37][38][39]. ...

Bayesian inversion and the Tomita–Takesaki modular group
  • Citing Article
  • March 2023

The Quarterly Journal of Mathematics

... Introduction.-As the conditional expectation is an essential concept in classical probability theory [1], many attempts have been made over the past few decades to generalize it to the quantum regime [2-9]. It has recently been recognized [8,9] that many concepts in quantum information science, including optimal Bayesian quantum estimation [2, 3], the Accardi-Cecchini generalized conditional expectation (GCE) [4], the weak values [5,6], quantum retrodiction [10,11], and quantum smoothing [12][13][14], can all be unified under a mathematical formalism of generalized conditional expectations (GCEs) [7], which can also be rigorously connected [15] to the concept of quantum states over time and generalized Bayes rules [16]. The GCEs have nonetheless provoked fierce debates regarding their meaning and usefulness, especially when it comes to the weak values [17,18]. ...

From time-reversal symmetry to quantum Bayes' rules
  • Citing Preprint
  • December 2022

... 20 In this case, inference can no longer be described by (classical) Bayes' theorem but requires a quantum generalization. Much recent work has been devoted to finding a generalization of Bayes' theorem to the quantum case, which has given rise to various different proposals for a quantum Bayesian inverse -see Ref. [42,43,19] for a recent categorical (process-diagrammatic) definition and Ref. [44] for an attempt at an axiomatic derivation. Once a definition for the Bayesian inverse has been fixed -and provided it exists 21 -we can perform a generalized abduction step in Sec. ...

Axioms for retrodiction: achieving time-reversal symmetry with a prior

... There is a prevailing viewpoint that fundamental physics should be based on a primitive notion of information. The theory of quantum states over time is a nascent approach to quantum theory that stems directly from such a viewpoint, formulating the dynamical flow of quantum information in a way which is directly analogous to spacetime and its relation to classical dynamics [4,5,7,13,21]. As opposed to a density operator which only encodes spatial correlations in quantum systems, quantum states over time encode spatiotemporal correlations which arise as a result of a quantum system evolving under quantum processes modeled by completely positive trace-preserving (CPTP) maps. ...

On quantum states over time