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1. Thermodynamic Overfitting and Generalization: Energetic Limits on Predictive Complexity

Author

Boyd, Alexander B., Crutchfield, James P., Gu, Mile, and Binder, Felix C.

Subjects
Condensed Matter - Statistical Mechanics
Abstract

Efficiently harvesting thermodynamic resources requires a precise understanding of their structure. This becomes explicit through the lens of information engines -- thermodynamic engines that use information as fuel. Maximizing the work harvested using available information is a form of physically-instantiated machine learning that drives information engines to develop complex predictive memory to store an environment's temporal correlations. We show that an information engine's complex predictive memory poses both energetic benefits and risks. While increasing memory facilitates detection of hidden patterns in an environment, it also opens the possibility of thermodynamic overfitting, where the engine dissipates additional energy in testing. To address overfitting, we introduce thermodynamic regularizers that incur a cost to engine complexity in training due to the physical constraints on the information engine. We demonstrate that regularized thermodynamic machine learning generalizes effectively. In particular, the physical constraints from which regularizers are derived improve the performance of learned predictive models. This suggests that the laws of physics jointly create the conditions for emergent complexity and predictive intelligence.

Published
2024

2. Parameter estimation for quantum jump unraveling

Author

Radaelli, Marco, Smiga, Joseph A., Landi, Gabriel T., and Binder, Felix C.

Subjects
Quantum Physics
Abstract

We consider the estimation of parameters encoded in the measurement record of a continuously monitored quantum system in the jump unraveling. This unraveling picture corresponds to a single-shot scenario, where information is continuously gathered. Here, it is generally difficult to assess the precision of the estimation procedure via the Fisher Information due to intricate temporal correlations and memory effects. In this paper we provide a full set of solutions to this problem. First, for multi-channel renewal processes we relate the Fisher Information to an underlying Markov chain and derive a easily computable expression for it. For non-renewal processes, we introduce a new algorithm that combines two methods: the monitoring operator method for metrology and the Gillespie algorithm which allows for efficient sampling of a stochastic form of the Fisher Information along individual quantum trajectories. We show that this stochastic Fisher Information satisfies useful properties related to estimation in the single-shot scenario. Finally, we consider the case where some information is lost in data compression/post-selection, and provide tools for computing the Fisher Information in this case. All scenarios are illustrated with instructive examples from quantum optics and condensed matter., Comment: 15+6 pages, 7 figures. Comments welcome

Published
2024

3. Probabilistic simulation supports generalizable intuitive physics

Author

Wang, Haoliang, Jedoui, Khaled, Venkatesh, Rahul, Binder, Felix Jedidja, Tenenbaum, Josh, Fan, Judith E., Yamins, Daniel, and Smith, Kevin A

Subjects
Psychology, Behavioral Science, Reasoning, Representation, Computational Modeling
Abstract

How do people perform general-purpose physical reasoning across a variety of scenarios in everyday life? Across two studies with seven different physical scenarios, we asked participants to predict whether or where two objects will make contact. People achieved high accuracy and were highly consistent with each other in their predictions. We hypothesize that this robust generalization is a consequence of mental simulations of noisy physics. We designed an "intuitive physics engine'' model to capture this generalizable simulation. We find that this model generalized in human-like ways to unseen stimuli and to a different query of predictions. We evaluated several state-of-the-art deep learning and scene feature models on the same task and found that they could not explain human predictions as well. This study provides evidence that human's robust generalization in physics predictions are supported by a probabilistic simulation model, and suggests the need for structure in learned dynamics models.

Published
2024

4. Understanding Physical Dynamics with Counterfactual World Modeling

Author

Venkatesh, Rahul, Chen, Honglin, Feigelis, Kevin, Bear, Daniel M., Jedoui, Khaled, Kotar, Klemen, Binder, Felix, Lee, Wanhee, Liu, Sherry, Smith, Kevin A., Fan, Judith E., and Yamins, Daniel L. K.

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

The ability to understand physical dynamics is critical for agents to act in the world. Here, we use Counterfactual World Modeling (CWM) to extract vision structures for dynamics understanding. CWM uses a temporally-factored masking policy for masked prediction of video data without annotations. This policy enables highly effective "counterfactual prompting" of the predictor, allowing a spectrum of visual structures to be extracted from a single pre-trained predictor without finetuning on annotated datasets. We demonstrate that these structures are useful for physical dynamics understanding, allowing CWM to achieve the state-of-the-art performance on the Physion benchmark., Comment: ECCV 2024. Project page at: https://neuroailab.github.io/cwm-physics/

Published
2023

5. Non-Ideal Measurement Heat Engines

Author

Panda, Abhisek, Binder, Felix C., and Vinjanampathy, Sai

Subjects
Quantum Physics
Abstract

We discuss the role of non-ideal measurements within the context of measurement engines by contrasting examples of measurement engines which have the same work output but with varying amounts of entanglement. Accounting for the cost of resetting, correlating the engine to a pointer state and also the cost of cooling the pointer state, we show that for a given work output, thermally correlated engines can outperform corresponding entanglement engines. We also show that the optimal efficiency of the thermally correlated measurement engine is achieved with a higher temperature pointer than the pointer temperature of the optimal entanglement engine., Comment: 6 pages, 2 figures, comments welcome

Published
2023

6. Stochastic metrology and the empirical distribution

Author

Smiga, Joseph A., Radaelli, Marco, Binder, Felix C., and Landi, Gabriel T.

Subjects
Condensed Matter - Statistical Mechanics, Mathematics - Statistics Theory, Quantum Physics
Abstract

We study the problem of parameter estimation in time series stemming from general stochastic processes, where the outcomes may exhibit arbitrary temporal correlations. In particular, we address the question of how much Fisher information is lost if the stochastic process is compressed into a single histogram, known as the empirical distribution. As we show, the answer is non-trivial due to the correlations between outcomes. We derive practical formulas for the resulting Fisher information for various scenarios, from generic stationary processes to discrete-time Markov chains to continuous-time classical master equations. The results are illustrated with several examples., Comment: 16 pages, 8 figures, 1 table

Published
2023
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7. Measuring and Modeling Physical Intrinsic Motivation

Author

Martinez, Julio, Binder, Felix, Wang, Haoliang, Haber, Nick, Fan, Judith, and Yamins, Daniel L. K.

Subjects
Computer Science - Artificial Intelligence, Computer Science - Machine Learning
Abstract

Humans are interactive agents driven to seek out situations with interesting physical dynamics. Here we formalize the functional form of physical intrinsic motivation. We first collect ratings of how interesting humans find a variety of physics scenarios. We then model human interestingness responses by implementing various hypotheses of intrinsic motivation including models that rely on simple scene features to models that depend on forward physics prediction. We find that the single best predictor of human responses is adversarial reward, a model derived from physical prediction loss. We also find that simple scene feature models do not generalize their prediction of human responses across all scenarios. Finally, linearly combining the adversarial model with the number of collisions in a scene leads to the greatest improvement in predictivity of human responses, suggesting humans are driven towards scenarios that result in high information gain and physical activity., Comment: 6 pages, 5 figures, accepted to CogSci 2023 with full paper publication in the proceedings

Published
2023

8. Trade-offs between precision and fluctuations in charging finite-dimensional quantum batteries

Author

Bakhshinezhad, Pharnam, Jablonski, Beniamin R., Binder, Felix C., and Friis, Nicolai

Subjects
Quantum Physics
Abstract

Within quantum thermodynamics, many tasks are modelled by processes that require work sources represented by out-of-equilibrium quantum systems, often dubbed quantum batteries, in which work can be deposited or from which work can be extracted. Here we consider quantum batteries modelled as finite-dimensional quantum systems initially in thermal equilibrium that are charged via cyclic Hamiltonian processes. We present optimal or near-optimal protocols for $N$ identical two-level systems and individual $d$-level systems with equally spaced energy gaps in terms of the charging precision and work fluctuations during the charging process. We analyze the trade-off between these figures of merit as well as the performance of local and global operations., Comment: 18 pages, 7 figures; revised protocol for minimizing work fluctuations

Published
2023
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9. A Gillespie algorithm for efficient simulation of quantum jump trajectories

Author

Radaelli, Marco, Landi, Gabriel T., and Binder, Felix C.

Subjects
Quantum Physics, Condensed Matter - Statistical Mechanics
Abstract

The jump unravelling of a quantum master equation decomposes the dynamics of an open quantum system into abrupt jumps, interspersed by periods of coherent dynamics where no jumps occur. Simulating these jump trajectories is computationally expensive, as it requires very small time steps to ensure convergence. This computational challenge is aggravated in regimes where the coherent, Hamiltonian dynamics are fast compared to the dissipative dynamics responsible for the jumps. Here, we present a quantum version of the Gillespie algorithm that bypasses this issue by directly constructing the waiting time distribution for the next jump to occur. In effect, this avoids the need for timestep discretisation altogether, instead evolving the system continuously from one jump to the next. We describe the algorithm in detail and discuss relevant limiting cases. To illustrate it we include four example applications of increasing physical complexity. These additionally serve to compare the performance of the algorithm to alternative approaches -- namely, the widely-used routines contained in the powerful Python library QuTip. We find significant gains in efficiency for our algorithm and discuss in which regimes these are most pronounced. Publicly available implementations of our code are provided in Julia and Mathematica., Comment: 13 pages, 4 figures. Comments welcome

Published
2023

10. Quantum measurements and equilibration: the emergence of objective reality via entropy maximisation

Author

Schwarzhans, Emanuel, Binder, Felix C., Huber, Marcus, and Lock, Maximilian P. E.

Subjects
Quantum Physics
Abstract

Textbook quantum physics features two types of dynamics, reversible unitary dynamics and irreversible measurements. The latter stands in conflict with the laws of thermodynamics and has evoked debate on what actually constitutes a measurement. With the help of modern quantum statistical mechanics, we take the first step in formalising the hypothesis that quantum measurements are instead driven by the natural tendency of closed systems to maximize entropy, a notion that we call the Measurement-Equilibration Hypothesis. In this paradigm, we investigate how objective measurement outcomes can emerge within an purely unitary framework, and find that: (i) the interactions used in standard measurement models fail to spontaneously feature emergent objectivity and (ii) while ideal projective measurements are impossible, we can (for a given form of Hamiltonian) approximate them exponentially well as we collect more physical systems together into an ``observer'' system. We thus lay the groundwork for self-contained models of quantum measurement, proposing improvements to our simple scheme., Comment: 7+6 pages, 1 figure

Published
2023

11. Advancing Cognitive Science and AI with Cognitive-AI Benchmarking

Author

Binder, Felix Jedidja, Cross, Logan Matthew, Friedman, Yoni, Hawkins, Robert, Yamins, Daniel L. K., and Fan, Judith E.

Subjects
Artificial Intelligence, Psychology, Robotics
Abstract

What are the current limits of AI models in explaining human cognition and behavior? How might approaches from the cognitive sciences drive the development of more robust and reliable AI systems? The goal of this workshop is bring together researchers across cognitive science and artificial intelligence (AI) to engage with these questions and identify opportunities to work together to advance progress in both fields. In particular, we propose Cognitive-AI Benchmarking as a particularly promising strategy --- that is, the community-coordinated establishment of common benchmarks, tools, and best practices for model-human comparisons across diverse and ecologically relevant domains and tasks. We will host a combination of talks, panel discussion, and breakout activities to: highlight past successes in Cognitive-AI Benchmarking and limitations of current approaches, share tools and best practices, and outline future challenges and goals for the field.

Published
2023

12. Humans choose visual subgoals to reduce cognitive cost

Author

Binder, Felix Jedidja, Mattar, Marcelo G, Kirsh, David, and Fan, Judith E.

Subjects
Psychology, Decision making, Problem Solving, Situated cognition, Spatial cognition
Abstract

Physical assembly is a difficult planning problem. Humans do it efficiently by breaking large problems into smaller, easier to solve portions. What governs which portions are chosen? We present a model that predicts that humans break assembly problems down to minimize cognitive costs. We test this by asking participants to choose which part of a tower they want to build next. Participants reliably choose the easier to solve subgoal out of two otherwise similar options. Beyond the immediate cognitive cost, participants also consider how difficult the rest of the tower will be to solve. A model that takes into account near-future cognitive costs best predicts participants' choices. These findings show that humans can estimate how difficult solving a subgoal will be, and that they choose subgoals to minimize immediate and future cognitive costs. These results help explain how humans make efficient use of cognitive resources to solve complex planning problems.

Published
2023

13. Work extraction from unknown quantum sources

Author

Šafránek, Dominik, Rosa, Dario, and Binder, Felix

Subjects
Quantum Physics, Condensed Matter - Quantum Gases, Condensed Matter - Statistical Mechanics
Abstract

Energy extraction is a central task in thermodynamics. In quantum physics, ergotropy measures the amount of work extractable under cyclic Hamiltonian control. As its full extraction requires perfect knowledge of the initial state, however, it does not characterize the work value of unknown or untrusted quantum sources. Fully characterizing such sources would require quantum tomography, which is prohibitively costly in experiments due to the exponential growth of required measurements and operational limitations. Here, we therefore derive a new notion of ergotropy applicable when nothing is known about the quantum states produced by the source, apart from what can be learned by performing only a single type of coarse-grained measurement. We find that in this case the extracted work is defined by the Boltzmann and observational entropy, in cases where the measurement outcomes are, or are not, used in the work extraction, respectively. This notion of ergotropy represents a realistic measure of extractable work, which can be used as the relevant figure of merit to characterize a quantum battery., Comment: 5+1(Appendix)+7(Supplemental) pages, 4 figures. Comments and questions welcome. v2: changed the interpretation of the coarse-grained extraction operations (former eq (6), now eq (7)). Appendix with examples added. Results unchanged. v3: technical details moved into a short appendix. Added explanatory figure for the extraction operations. Added extra proof in the Supplemental Material

Published
2022
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14. Fisher information of correlated stochastic processes

Author

Radaelli, Marco, Landi, Gabriel T., Modi, Kavan, and Binder, Felix C.

Subjects
Quantum Physics, Condensed Matter - Statistical Mechanics, Mathematics - Statistics Theory
Abstract

Many real-world tasks include some kind of parameter estimation, i.e., determination of a parameter encoded in a probability distribution. Often, such probability distributions arise from stochastic processes. For a stationary stochastic process with temporal correlations, the random variables that constitute it are identically distributed but not independent. This is the case, for instance, for quantum continuous measurements. In this paper we prove two fundamental results concerning the estimation of parameters encoded in a memoryful stochastic process. First, we show that for processes with finite Markov order, the Fisher information is always asymptotically linear in the number of outcomes, and determined by the conditional distribution of the process' Markov order. Second, we prove with suitable examples that correlations do not necessarily enhance the metrological precision. In fact, we show that unlike for entropic information quantities, in general nothing can be said about the sub- or super-additivity of the joint Fisher information, in the presence of correlations. We discuss how the type of correlations in the process affects the scaling. We then apply these results to the case of thermometry on a spin chain., Comment: 16 pages, 6 figures; final version

Published
2022
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15. Physion: Evaluating Physical Prediction from Vision in Humans and Machines

Author

Bear, Daniel M., Wang, Elias, Mrowca, Damian, Binder, Felix J., Tung, Hsiao-Yu Fish, Pramod, R. T., Holdaway, Cameron, Tao, Sirui, Smith, Kevin, Sun, Fan-Yun, Fei-Fei, Li, Kanwisher, Nancy, Tenenbaum, Joshua B., Yamins, Daniel L. K., and Fan, Judith E.

Subjects
Computer Science - Artificial Intelligence, Computer Science - Computer Vision and Pattern Recognition, I.2.10, I.4.8, I.5
Abstract

While current vision algorithms excel at many challenging tasks, it is unclear how well they understand the physical dynamics of real-world environments. Here we introduce Physion, a dataset and benchmark for rigorously evaluating the ability to predict how physical scenarios will evolve over time. Our dataset features realistic simulations of a wide range of physical phenomena, including rigid and soft-body collisions, stable multi-object configurations, rolling, sliding, and projectile motion, thus providing a more comprehensive challenge than previous benchmarks. We used Physion to benchmark a suite of models varying in their architecture, learning objective, input-output structure, and training data. In parallel, we obtained precise measurements of human prediction behavior on the same set of scenarios, allowing us to directly evaluate how well any model could approximate human behavior. We found that vision algorithms that learn object-centric representations generally outperform those that do not, yet still fall far short of human performance. On the other hand, graph neural networks with direct access to physical state information both perform substantially better and make predictions that are more similar to those made by humans. These results suggest that extracting physical representations of scenes is the main bottleneck to achieving human-level and human-like physical understanding in vision algorithms. We have publicly released all data and code to facilitate the use of Physion to benchmark additional models in a fully reproducible manner, enabling systematic evaluation of progress towards vision algorithms that understand physical environments as robustly as people do., Comment: 28 pages

Published
2021

16. Visual scoping operations for physical assembly

Author

Binder, Felix J, Mattar, Marcelo M, Kirsh, David, and Fan, Judith E

Subjects
Computer Science - Artificial Intelligence, Computer Science - Robotics, I.2
Abstract

Planning is hard. The use of subgoals can make planning more tractable, but selecting these subgoals is computationally costly. What algorithms might enable us to reap the benefits of planning using subgoals while minimizing the computational overhead of selecting them? We propose visual scoping, a strategy that interleaves planning and acting by alternately defining a spatial region as the next subgoal and selecting actions to achieve it. We evaluated our visual scoping algorithm on a variety of physical assembly problems against two baselines: planning all subgoals in advance and planning without subgoals. We found that visual scoping achieves comparable task performance to the subgoal planner while requiring only a fraction of the total computational cost. Together, these results contribute to our understanding of how humans might make efficient use of cognitive resources to solve complex planning problems.

Published
2021

17. Landauer vs. Nernst: What is the True Cost of Cooling a Quantum System?

Author

Taranto, Philip, Bakhshinezhad, Faraj, Bluhm, Andreas, Silva, Ralph, Friis, Nicolai, Lock, Maximilian P. E., Vitagliano, Giuseppe, Binder, Felix C., Debarba, Tiago, Schwarzhans, Emanuel, Clivaz, Fabien, and Huber, Marcus

Subjects
Quantum Physics
Abstract

Thermodynamics connects our knowledge of the world to our capability to manipulate and thus to control it. This crucial role of control is exemplified by the third law of thermodynamics, Nernst's unattainability principle, which states that infinite resources are required to cool a system to absolute zero temperature. But what are these resources and how should they be utilized? And how does this relate to Landauer's principle that famously connects information and thermodynamics? We answer these questions by providing a framework for identifying the resources that enable the creation of pure quantum states. We show that perfect cooling is possible with Landauer energy cost given infinite time or control complexity. However, such optimal protocols require complex unitaries generated by an external work source. Restricting to unitaries that can be run solely via a heat engine, we derive a novel Carnot-Landauer limit, along with protocols for its saturation. This generalizes Landauer's principle to a fully thermodynamic setting, leading to a unification with the third law and emphasizes the importance of control in quantum thermodynamics., Comment: 13.5 pages, 4 figures, 44 pages of appendices; close to published version

Published
2021
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18. Quantum Coherence and Ergotropy

Author

Francica, Gianluca, Binder, Felix C., Guarnieri, Giacomo, Mitchison, Mark T., Goold, John, and Plastina, Francesco

Subjects
Quantum Physics, Condensed Matter - Statistical Mechanics
Abstract

Constraints on work extraction are fundamental to our operational understanding of the thermodynamics of both classical and quantum systems. In the quantum setting, finite-time control operations typically generate coherence in the instantaneous energy eigenbasis of the dynamical system. Thermodynamic cycles can, in principle, be designed to extract work from this non-equilibrium resource. Here, we isolate and study the quantum coherent component to the work yield in such protocols. Specifically, we identify a coherent contribution to the ergotropy (the maximum amount of unitarily extractable work via cyclical variation of Hamiltonian parameters). We show this by dividing the optimal transformation into an incoherent operation and a coherence extraction cycle. We obtain bounds for both the coherent and incoherent parts of the extractable work and discuss their saturation in specific settings. Our results are illustrated with several examples, including finite-dimensional systems and bosonic Gaussian states that describe recent experiments on quantum heat engines with a quantized load., Comment: v1: 5+3 pages, 3 figures. Comments welcome. v2: Accepted version

Published
2020
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19. Boosting on the shoulders of giants in quantum device calibration

Author

Wozniakowski, Alex, Thompson, Jayne, Gu, Mile, and Binder, Felix

Subjects
Quantum Physics, Computer Science - Machine Learning, Statistics - Machine Learning
Abstract

Traditional machine learning applications, such as optical character recognition, arose from the inability to explicitly program a computer to perform a routine task. In this context, learning algorithms usually derive a model exclusively from the evidence present in a massive dataset. Yet in some scientific disciplines, obtaining an abundance of data is an impractical luxury, however; there is an explicit model of the domain based upon previous scientific discoveries. Here we introduce a new approach to machine learning that is able to leverage prior scientific discoveries in order to improve generalizability over a scientific model. We show its efficacy in predicting the entire energy spectrum of a Hamiltonian on a superconducting quantum device, a key task in present quantum computer calibration. Our accuracy surpasses the current state-of-the-art by over $20\%.$ Our approach thus demonstrates how artificial intelligence can be further enhanced by "standing on the shoulders of giants."

Published
2020

20. Stabilizing Open Quantum Batteries by Sequential Measurements

Author

Gherardini, Stefano, Campaioli, Francesco, Caruso, Filippo, and Binder, Felix C.

Subjects
Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

A quantum battery is a work reservoir that stores energy in quantum degrees of freedom. When immersed in an environment an open quantum battery needs to be stabilized against free energy leakage into the environment. For this purpose we here propose a simple protocol that relies on projective measurement and obeys a second-law like inequality for the battery entropy production rate., Comment: 5+5 pages, 3+2 figures

Published
2019
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21. Visual scoping operations for physical assembly

Author

Binder, Felix Jedidja, Mattar, Marcelo G, Kirsh, David, and Fan, Judith E.

Subjects
cognitive science
Abstract

Planning is hard. The use of subgoals can make planning more tractable, but selecting these subgoals is computationally costly. What algorithms might enable us to reap the benefits of planning using subgoals while minimizing the computational overhead of selecting them? We propose visual scoping, a strategy that interleaves planning and acting by alternately defining a spatial region as the next subgoal and selecting actions to achieve it. We evaluated our visual scoping algorithm on a variety of physical assembly problems against two baselines: planning all subgoals in advance and planning without subgoals. We found that visual scoping achieves comparable task performance to the subgoal planner while requiring only a fraction of the total computational cost.Together, these results contribute to our understanding of how humans might make efficient use of cognitive resources to solve complex planning problems.

Published
2021

22. Cognitive cost and information gain trade off in a large-scale number guessing game

Author

Binder, Felix Jedidja, Jones, Cameron R, Kaufman, Robert A, Lin, Naomi T, Poole, Crystal R, and Vul, Ed

Subjects
cognitive science
Abstract

How do people ask questions to zero in on a correct answer? Although we can formally define an optimal query to maximize information gain, algorithms for finding this optimal guess may impose large resource costs in space (memory) and time (computation). To understand how people trade off the information gain and the computational difficulty of choosing the ideal query, we turned to a large dataset of 380,000 guesses made during a number-guessing game with Amazon Alexa. We analyzed whether the arithmetic difficulty of following the optimal strategy predicts how far a guess deviates from theoretically optimal query. We find that when memory load is higher, and when more arithmetic operations need to be performed, human guesses deviate more from the most informative query.These results suggest human computational resource constraints limit how people seek out informative questions.

Published
2021

23. Measures of distinguishability between stochastic processes

Author

Yang, Chengran, Binder, Felix C., Gu, Mile, and Elliott, Thomas J.

Subjects
Condensed Matter - Statistical Mechanics, Quantum Physics
Abstract

Quantifying how distinguishable two stochastic processes are lies at the heart of many fields, such as machine learning and quantitative finance. While several measures have been proposed for this task, none have universal applicability and ease of use. In this Letter, we suggest a set of requirements for a well-behaved measure of process distinguishability. Moreover, we propose a family of measures, called divergence rates, that satisfy all of these requirements. Focussing on a particular member of this family -- the co-emission divergence rate -- we show that it can be computed efficiently, behaves qualitatively similar to other commonly-used measures in their regimes of applicability, and remains well-behaved in scenarios where other measures break down.

Published
2019
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24. Thermodynamic resources in continuous-variable quantum systems

Author

Narasimhachar, Varun, Assad, Syed, Binder, Felix C., Thompson, Jayne, Yadin, Benjamin, and Gu, Mile

Subjects
Quantum Physics, Condensed Matter - Statistical Mechanics, Physics - Optics
Abstract

Thermodynamic resources, beyond their well-known usefulness in work extraction and other thermodynamic tasks, are often important also in tasks that are not evidently thermodynamic. Here we develop a framework for identifying such resources in diverse applications of bosonic continuous-variable systems. Introducing the class of bosonic linear thermal operations to model operationally-feasible processes, we apply this model to identify uniquely quantum properties of bosonic states that refine classical notions of thermodynamic resourcefulness. Among these are (1) a suite of temperature-like quantities generalizing the equilibrium temperature to quantum, non-equilibrium scenarios; (2) signal-to-noise ratios quantifying a system's capacity to carry information in phase-space displacement; and (3) well-established non-classicality measures quantifying the resolution in sensing and parameter estimation tasks., Comment: 9 pages (6 figures), 4-page supplemental material

Published
2019
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25. Extreme dimensionality reduction with quantum modelling

Author

Elliott, Thomas J., Yang, Chengran, Binder, Felix C., Garner, Andrew J. P., Thompson, Jayne, and Gu, Mile

Subjects
Quantum Physics, Condensed Matter - Statistical Mechanics, Computer Science - Information Theory
Abstract

Effective and efficient forecasting relies on identification of the relevant information contained in past observations -- the predictive features -- and isolating it from the rest. When the future of a process bears a strong dependence on its behaviour far into the past, there are many such features to store, necessitating complex models with extensive memories. Here, we highlight a family of stochastic processes whose minimal classical models must devote unboundedly many bits to tracking the past. For this family, we identify quantum models of equal accuracy that can store all relevant information within a single two-dimensional quantum system (qubit). This represents the ultimate limit of quantum compression and highlights an immense practical advantage of quantum technologies for the forecasting and simulation of complex systems., Comment: 6+3 pages, 3+1 figures

Published
2019
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26. Optimal stochastic modelling with unitary quantum dynamics

Author

Liu, Qing, Elliott, Thomas. J., Binder, Felix. C., Di Franco, Carlo, and Gu, Mile

Subjects
Quantum Physics, Condensed Matter - Statistical Mechanics
Abstract

Identifying and extracting the past information relevant to the future behaviour of stochastic processes is a central task in the quantitative sciences. Quantum models offer a promising approach to this, allowing for accurate simulation of future trajectories whilst using less past information than any classical counterpart. Here we introduce a class of phase-enhanced quantum models, representing the most general means of causal simulation with a unitary quantum circuit. We show that the resulting constructions can display advantages over previous state-of-art methods - both in the amount of information they need to store about the past, and in the minimal memory dimension they require to store this information. Moreover, we find that these two features are generally competing factors in optimisation - leading to an ambiguity in what constitutes the optimal model - a phenomenon that does not manifest classically. Our results thus simultaneously offer new quantum advantages for stochastic simulation, and illustrate further qualitative differences in behaviour between classical and quantum notions of complexity., Comment: 9 pages, 5 figures

Published
2018
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28. Operational resource theory of continuous-variable nonclassicality

Author

Yadin, Benjamin, Binder, Felix C., Thompson, Jayne, Narasimhachar, Varun, Gu, Mile, and Kim, M. S.

Subjects
Quantum Physics
Abstract

Genuinely quantum states of a harmonic oscillator may be distinguished from their classical counterparts by the Glauber-Sudarshan P-representation -- a state lacking a positive P-function is said to be nonclassical. In this paper, we propose a general operational framework for studying nonclassicality as a resource in networks of passive linear elements and measurements with feed-forward. Within this setting, we define new measures of nonclassicality based on the quantum fluctuations of quadratures, as well as the quantum Fisher information of quadrature displacements. These lead to fundamental constraints on the manipulation of nonclassicality, especially its concentration into subsystems, that apply to generic multi-mode non-Gaussian states. Special cases of our framework include no-go results in the concentration of squeezing and a complete hierarchy of nonclassicality for single mode Gaussian states., Comment: 21 pages, 7 figures; comments welcome; close to published version

Published
2018
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29. Matrix Product States for Quantum Stochastic Modelling

Author

Yang, Chengran, Binder, Felix C., Narasimhachar, Varun, and Gu, Mile

Subjects
Quantum Physics, Condensed Matter - Statistical Mechanics
Abstract

In stochastic modeling, there has been a significant effort towards finding predictive models that predict a stochastic process' future using minimal information from its past. Meanwhile, in condensed matter physics, matrix product states (MPS) are known as a particularly efficient representation of 1D spin chains. In this Letter, we associate each stochastic process with a suitable quantum state of a spin chain. We then show that the optimal predictive model for the process leads directly to an MPS representation of the associated quantum state. Conversely, MPS methods offer a systematic construction of the best known quantum predictive models. This connection allows an improved method for computing the quantum memory needed for generating optimal predictions. We prove that this memory coincides with the entanglement of the associated spin chain across the past-future bipartition., Comment: 12 pages; 9 figures; Comments welcome

Published
2018
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30. Speeding up Thermalisation via Open Quantum System Variational Optimisation

Author

Suri, Nishchay, Binder, Felix C., Muralidharan, Bhaskaran, and Vinjanampathy, Sai

Subjects
Quantum Physics
Abstract

Optimizing open quantum system evolution is an important step on the way to achieving quantum computing and quantum thermodynamic tasks. In this article, we approach optimisation via variational principles and derive an open quantum system variational algorithm explicitly for Lindblad evolution in Liouville space. As an example of such control over open system evolution, we control the thermalisation of a qubit attached to a thermal Lindbladian bath with a damping rate $\gamma$. Since thermalisation is an asymptotic process and the variational algorithm we consider is for fixed time, we present a way to discuss the potential speedup of thermalisation that can be expected from such variational algorithms., Comment: 10 pages, 4 figures, comments welcome

Published
2017
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31. Tightening Quantum Speed Limits for Almost All States

Author

Campaioli, Francesco, Pollock, Felix A., Binder, Felix C., and Modi, Kavan

Subjects
Quantum Physics
Abstract

Conventional quantum speed limits perform poorly for mixed quantum states: They are generally not tight and often significantly underestimate the fastest possible evolution speed. To remedy this, for unitary driving, we derive two quantum speed limits that outperform the traditional bounds for almost all quantum states. Moreover, our bounds are significantly simpler to compute as well as experimentally more accessible. Our bounds have a clear geometric interpretation; they arise from the evaluation of the angle between generalized Bloch vectors., Comment: Updated and revised version; 5 pages, 2 figures, 1 page appendix

Published
2017
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32. A practical, unitary simulator for non-Markovian complex processes

Author

Binder, Felix C., Thompson, Jayne, and Gu, Mile

Subjects
Quantum Physics, Condensed Matter - Statistical Mechanics
Abstract

Stochastic processes are as ubiquitous throughout the quantitative sciences as they are notorious for being difficult to simulate and predict. In this letter we propose a unitary quantum simulator for discrete-time stochastic processes which requires less internal memory than any classical analogue throughout the simulation. The simulator's internal memory requirements equal those of the best previous quantum models. However, in contrast to previous models it only requires a (small) finite-dimensional Hilbert space. Moreover, since the simulator operates unitarily throughout, it avoids any unnecessary information loss. We provide a stepwise construction for simulators for a large class of stochastic processes hence directly opening the possibility for experimental implementations with current platforms for quantum computation. The results are illustrated for an example process., Comment: 12 pages, 5 figures

Published
2017
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33. Enhancing the charging power of quantum batteries

Author

Campaioli, Francesco, Pollock, Felix A., Binder, Felix C., Céleri, Lucas C., Goold, John, Vinjanampathy, Sai, and Modi, Kavan

Subjects
Quantum Physics, Condensed Matter - Statistical Mechanics
Abstract

Can collective quantum effects make a difference in a meaningful thermodynamic operation? Focusing on energy storage and batteries, we demonstrate that quantum mechanics can lead to an enhancement in the amount of work deposited per unit time, i.e., the charging power, when $N$ batteries are charged collectively. We first derive analytic upper bounds for the collective \emph{quantum advantage} in charging power for two choices of constraints on the charging Hamiltonian. We then highlight the importance of entanglement by proving that the quantum advantage vanishes when the collective state of the batteries is restricted to be in the separable ball. Finally, we provide an upper bound to the achievable quantum advantage when the interaction order is restricted, i.e., at most $k$ batteries are interacting. Our result is a fundamental limit on the advantage offered by quantum technologies over their classical counterparts as far as energy deposition is concerned., Comment: In this new updated version Theorem 1 has been changed with Proposition 1. The paper has been published on PRL, and DOI included accordingly

Published
2016
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35. Quantacell: Powerful charging of quantum batteries

Author

Binder, Felix C., Vinjanampathy, Sai, Modi, Kavan, and Goold, John

Subjects
Quantum Physics, Condensed Matter - Statistical Mechanics
Abstract

We study the problem of charging a quantum battery in finite time. We demonstrate an analytical optimal protocol for the case of a single qubit. Extending this analysis to an array of N qubits, we demonstrate that an N-fold advantage in power per qubit can be achieved when global operations are permitted. The exemplary analytic argument for this quantum advantage in the charging power is backed up by numerical analysis using optimal control techniques. It is demonstrated that the quantum advantage for power holds when, with cyclic operation in mind, initial and final states are required to be separable., Comment: 11 pages, 3 figures, comments welcome

Published
2015
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36. Work, heat, and power of quantum processes

Author

Binder, Felix Christoph and Vedral, Vlatko

Subjects
530.12
Abstract

The central purpose of this thesis is to study the familiar processes of quantum information theory from a thermodynamic point of view. Chapter 1 introduces equilibrium thermodynamics and its laws. The laws are then motivated in a statistical mechanics approach which explicitly employs the language of quantum information theory. Chapter 2 is dedicated to the concept of work extraction, in particular in non- equilibrium scenarios. In this context a generalised notion of equilibrium called passivity is introduced. The chapter's final section gives an introduction and an overview of various approaches to work extraction ranging from classical to explicitly quantum scenarios. Chapter 3 considers the question of powerful unitary operations. Focussing on the case of qubits (or rather wits, short for 'work bits') the chapter's first result is an explicit protocol for maximally powerful driving for any given initial state. Building onto this, the chapter's second main result is a proof that the evolution time (and hence the power of the corresponding work deposition process) can be decreased by a factor of 1/N for an array of N wits if global driving is permitted (rather than individual driving in parallel). Lastly, the thermodynamics of completely-positive and trace-preserving (CPTP) maps is considered in Chapter 4. It is shown that the energy change during such a process can be split into three parts: a work-like equilibrium contribution, a heat-like equilibrium contribution, and a third genuinely non-equilibrium energy difference. All three terms obtain their meaning when considering how much work can be extracted from the input and output state of the CPTP process, respectively. Furthermore, the identification of work and heat in this manner complies with a recently published version of the second law, which applies to the same class of processes. This is demonstrated by considering unital and thermal maps.

Published
2016

37. Quantum thermodynamics of general quantum processes

Author

Binder, Felix C., Vinjanampathy, Sai, Modi, Kavan, and Goold, John

Subjects
Quantum Physics, Condensed Matter - Statistical Mechanics
Abstract

Accurately describing work extraction from a quantum system is a central objective for the extension of thermodynamics to individual quantum systems. The concepts of work and heat are surprisingly subtle when generalizations are made to arbitrary quantum states. We formulate an operational thermodynamics suitable for application to an open quantum system undergoing quantum evolution under a general quantum process by which we mean a completely-positive and trace-preserving map. We derive an operational first law of thermodynamics for such processes and show consistency with the second law. We show that heat, from the first law, is positive when the input state of the map majorises the output state. Moreover, the change in entropy is also positive for the same majorisation condition. This makes a strong connection between the two operational laws of thermodynamics., Comment: 6 pages, 1 figure

Published
2014
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45. Landauer Versus Nernst: What is the True Cost of Cooling a Quantum System?

Author

Taranto, Philip, primary, Bakhshinezhad, Faraj, additional, Bluhm, Andreas, additional, Silva, Ralph, additional, Friis, Nicolai, additional, Lock, Maximilian P.E., additional, Vitagliano, Giuseppe, additional, Binder, Felix C., additional, Debarba, Tiago, additional, Schwarzhans, Emanuel, additional, Clivaz, Fabien, additional, and Huber, Marcus, additional

Published
2023
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46. Trade-offs between precision and fluctuations in charging finite-dimensional quantum systems

Author

Bakhshinezhad, Faraj, Jablonski, Beniamin R., Binder, Felix C., and Friis, Nicolai

Subjects
Quantum Physics, FOS: Physical sciences, Quantum Physics (quant-ph)
Abstract

Within quantum thermodynamics, many tasks are modelled by processes that require work sources represented by out-of-equilibrium quantum systems, often dubbed quantum batteries, in which work can be deposited or from which work can be extracted. Here we consider quantum batteries modelled as finite-dimensional quantum systems initially in thermal equilibrium that are charged via cyclic Hamiltonian processes. We present optimal or near-optimal protocols for $N$ identical two-level systems and individual $d$-level systems with equally spaced energy gaps in terms of the charging precision and work fluctuations during the charging process. We analyze the trade-off between these figures of merit as well as the performance of local and global operations., Comment: 14+2 pages, 7 figures

Published
2023
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50. Landauer vs. Nernst:What is the True Cost of Cooling a Quantum System?

Author

Taranto, Philip, Bakhshinezhad, Faraj, Bluhm, Andreas, Silva, Ralph, Friis, Nicolai, Lock, Maximilian P. E., Vitagliano, Giuseppe, Binder, Felix C., Debarba, Tiago, Schwarzhans, Emanuel, Clivaz, Fabien, and Huber, Marcus

Subjects
quant-ph
Abstract

Thermodynamics connects our knowledge of the world to our capability to manipulate and thus to control it. This crucial role of control is exemplified by the third law of thermodynamics, Nernst's unattainability principle, stating that infinite resources are required to cool a system to absolute zero temperature. But what are these resources? And how does this relate to Landauer's principle that famously connects information and thermodynamics? We answer these questions by providing a framework for identifying the resources that enable the creation of pure quantum states. We show that perfect cooling is possible with Landauer energy cost given infinite time or control complexity. Within the context of resource theories of quantum thermodynamics, we derive a Carnot-Landauer limit, along with protocols for its saturation. This generalises Landauer's principle to a fully thermodynamic setting, leading to a unification with the third law and emphasising the importance of control in quantum thermodynamics.

Published
2021

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