Your search keyword '"Weidner, Carrie"' showing total 43 results

1. Spatial calibration of high-density absorption imaging

Author

Vibel, Toke, Christensen, Mikkel Berg, Kristensen, Mick Althoff, Thuesen, Jeppe Juhl, Stokholm, Laurits Nikolaj, Weidner, Carrie Ann, and Arlt, Jan Joachim

Subjects

Physics - Atomic Physics, Condensed Matter - Quantum Gases

Abstract

The accurate determination of atom numbers is an ubiquitous problem in the field of ultracold atoms. For modest atom numbers, absolute calibration techniques are available, however, for large numbers and high densities, the available techniques neglect many-body scattering processes. Here, a spatial calibration technique for time-of-flight absorption images of ultracold atomic clouds is presented. The calibration is obtained from radially averaged absorption images and we provide a practical guide to the calibration process. It is shown that the calibration coefficient scales linearly with optical density and depends on the absorbed photon number for the experimental conditions explored here. This allows for the direct inclusion of a spatially dependent calibration in the image analysis. For typical ultracold atom clouds the spatial calibration technique leads to corrections in the detected atom number up to $\approx\! 12\,\%$ and temperature up to $\approx \!14\,\%$ in comparison to previous calibration techniques. The technique presented here addresses a major difficulty in absorption imaging of ultracold atomic clouds and prompts further theoretical work to understand the scattering processes in ultracold dense clouds of atoms for accurate atom number calibration.

Published

2024

2. Error Correcting States in Ultracold Atoms

Author

Kendell, Harry C. P., Ferranti, Giacomo, and Weidner, Carrie A.

Subjects

Quantum Physics, Physics - Atomic Physics

Abstract

We demonstrate a method for encoding Gottesman-Kitaev-Preskill (GKP) error-correcting qubits with single ultracold atoms trapped in individual sites of a deep optical lattice. Using quantum optimal control protocols, we demonstrate the generation of GKP qubit states with 10 dB squeezing, which is the current minimum allowable squeezing level for use in surface code error correction. States are encoded in the vibrational levels of the individual lattice sites and generated via phase modulation of the lattice potential. Finally, we provide a feasible experimental protocol for the realization of these states. Our protocol opens up possibilities for generating large arrays of atomic GKP states for continuous-variable quantum information.

Published

2023

3. Three-dimensional imaging of single atoms in an optical lattice via helical point-spread-function engineering

Author

Legrand, Tangi, Winkelmann, Falk-Richard, Alt, Wolfgang, Meschede, Dieter, Alberti, Andrea, and Weidner, Carrie A.

Subjects

Quantum Physics

Abstract

We demonstrate a method for determining the three-dimensional location of single atoms in a quantum gas microscopy system using a phase-only spatial light modulator to modify the point-spread function of the high-resolution imaging system. Here, the typical diffracted spot generated by a single atom as a point source is modified to a double spot that rotates as a function of the atom's distance from the focal plane of the imaging system. We present and numerically validate a simple model linking the rotation angle of the point-spread function with the distance to the focal plane. We show that, when aberrations in the system are carefully calibrated and compensated for, this method can be used to determine an atom's position to within a single lattice site in a single experimental image, extending quantum simulation with microscopy systems further into the regime of three dimensions., Comment: Accepted version

Published

2023

4. Disturbance-agnostic robust performance with structured uncertainties and initial state error in classical versus quantum oscillatory systems

Author

Jonckheere, Edmond, Schirmer, Sophie G., Langbein, Frank C., Weidner, Carrie A., and O'Neil, Sean

Subjects

Quantum Physics, Electrical Engineering and Systems Science - Systems and Control

Abstract

A method to quantify robust performance for situations where structured parameter variations and initial state errors rather than extraneous disturbances are the main performance limiting factors is presented. The approach is based on the error dynamics, the difference between nominal and perturbed dynamics, driven by either the unperturbed or perturbed state, rather than an artificially imposed disturbance. The unperturbed versus perturbed dichotomy can be interpreted as the relative error dynamics scaled by either the unperturbed or perturbed dynamics. The error dynamics driven by unperturbed state has the unique feature of decoupling the effect of physically meaningful uncertainties from an additive disturbance. The perturbed case offers the possibility to side-step Structured Singular Value (SSV) computations. Applications to a lightly damped mechanical system and a slowly dephasing quantum system demonstrate the usefulness of the concepts across a broad range of systems. Finally, a fixed-point algorithm specifically developed for quantum systems with state transitions depending in a nonlinear fashion on uncertainties is proposed as the substitute for classical SSV., Comment: 11 pages, 5 figures, and 1 table

Published

2023

5. Sample-efficient Model-based Reinforcement Learning for Quantum Control

Author

Khalid, Irtaza, Weidner, Carrie A., Jonckheere, Edmond A., Shermer, Sophie G., and Langbein, Frank C.

Subjects

Quantum Physics, Computer Science - Artificial Intelligence, Computer Science - Machine Learning

Abstract

We propose a model-based reinforcement learning (RL) approach for noisy time-dependent gate optimization with improved sample complexity over model-free RL. Sample complexity is the number of controller interactions with the physical system. Leveraging an inductive bias, inspired by recent advances in neural ordinary differential equations (ODEs), we use an auto-differentiable ODE parametrised by a learnable Hamiltonian ansatz to represent the model approximating the environment whose time-dependent part, including the control, is fully known. Control alongside Hamiltonian learning of continuous time-independent parameters is addressed through interactions with the system. We demonstrate an order of magnitude advantage in the sample complexity of our method over standard model-free RL in preparing some standard unitary gates with closed and open system dynamics, in realistic numerical experiments incorporating single shot measurements, arbitrary Hilbert space truncations and uncertainty in Hamiltonian parameters. Also, the learned Hamiltonian can be leveraged by existing control methods like GRAPE for further gradient-based optimization with the controllers found by RL as initializations. Our algorithm that we apply on nitrogen vacancy (NV) centers and transmons in this paper is well suited for controlling partially characterised one and two qubit systems., Comment: 14+10 pages, 6+6 figures, revised version

Published

2023

6. The impact of an interactive visualization and simulation tool on learning quantum physics: Results of an eye-tracking study

Author

Küchemann, Stefan, Ubben, Malte, Dzsotjan, David, Mukhametov, Sergey, Weidner, Carrie A., Qerimi, Linda, Kuhn, Jochen, Heusler, Stefan, and Sherson, Jacob F.

Subjects

Physics - Physics Education

Abstract

Employing scientific practices to obtain and use information is one of the central facets of next generation science standards. Especially in quantum technology education, the ability to employ such practices is an essential skill to foster both academic success and technological development. In order to help educators design effective instructions, the comparison between novices' and experts' eye movements allows the identification of efficient information extraction and integration strategies. In this work, we compare the gaze behavior of experts and novices while solving problems in quantum physics using an interactive simulation tool, Quantum Composer, which displays information via multiple external representations (numerical values, equations, graphs). During two reasoning tasks, we found that metarepresentational competences were crucial for successful engagement with the simulation tool. The analysis of the gaze behavior revealed that visual attention on a graph plays a major role and redundant numerical information is ignored. Furthermore, the total dwell time on relevant and irrelevant areas is predictive for the score in the second task. Therefore, the results demonstrate which difficulties novices encounter when using simulation tools and provides insights for how to design effective instructions in quantum technology education guided by experts' gaze behavior., Comment: 14 pages, 8 Figures, 3 Tables

Published

2023

7. Statistically Characterising Robustness and Fidelity of Quantum Controls and Quantum Control Algorithms

Author

Khalid, Irtaza, Weidner, Carrie A., Jonckheere, Edmond A., Shermer, Sophie G., and Langbein, Frank C.

Subjects

Quantum Physics

Abstract

Robustness of quantum operations or controls is important to build reliable quantum devices. The robustness-infidelity measure (RIM$_p$) is introduced to statistically quantify the robustness and fidelity of a controller as the p-order Wasserstein distance between the fidelity distribution of the controller under any uncertainty and an ideal fidelity distribution. The RIM$_p$ is the p-th root of the p-th raw moment of the infidelity distribution. Using a metrization argument, we justify why RIM$_1$ (the average infidelity) suffices as a practical robustness measure. Based on the RIM$_p$, an algorithmic robustness-infidelity measure (ARIM) is developed to quantify the expected robustness and fidelity of controllers found by a control algorithm. The utility of the RIM and ARIM is demonstrated by considering the problem of robust control of spin-$\tfrac{1}{2}$ networks using energy landscape shaping subject to Hamiltonian uncertainty. The robustness and fidelity of individual control solutions as well as the expected robustness and fidelity of controllers found by different popular quantum control algorithms are characterized. For algorithm comparisons, stochastic and non-stochastic optimization objectives are considered, with the goal of effective RIM optimization in the latter. Although high fidelity and robustness are often conflicting objectives, some high fidelity, robust controllers can usually be found, irrespective of the choice of the quantum control algorithm. However, for noisy optimization objectives, adaptive sequential decision making approaches such as reinforcement learning have a cost advantage compared to standard control algorithms and, in contrast, the infidelities obtained are more consistent with higher RIM values for low noise levels., Comment: 13+11 pages, 6+10 figures, revised version, accepted by Phys. Rev. A

Published

2022

8. Direct measurement of the Wigner function of atoms in an optical trap

Author

Winkelmann, Falk-Richard G., Weidner, Carrie A., Ramola, Gautam, Alt, Wolfgang, Meschede, Dieter, and Alberti, Andrea

Subjects

Quantum Physics, Physics - Atomic Physics

Abstract

We present a scheme that uses Ramsey interferometry to directly probe the Wigner function of a neutral atom confined in an optical trap. The proposed scheme relies on the well-established fact that the Wigner function at a given point $(x,p)$ in phase space is proportional to the expectation value of the parity operator relative to that point. In this work, we show that parity-even and parity-odd motional states can be mapped to two distinct internal states of the atom by using state-dependent trapping potentials. The Wigner function can thus be measured point-by-point in phase space with a single, direct measurement of the internal state population. Numerical simulations show that the scheme is robust in that it applies not only to deep, harmonic potentials but also to shallower, anharmonic traps., Comment: 10 pages, 5 figures

Published

2022

9. Quantum Games and Interactive Tools for Quantum Technologies Outreach and Education

Author

Seskir, Zeki C., Migdał, Piotr, Weidner, Carrie, Anupam, Aditya, Case, Nicky, Davis, Noah, Decaroli, Chiara, Ercan, İlke, Foti, Caterina, Gora, Paweł, Jankiewicz, Klementyna, La Cour, Brian R., Malo, Jorge Yago, Maniscalco, Sabrina, Naeemi, Azad, Nita, Laurentiu, Parvin, Nassim, Scafirimuto, Fabio, Sherson, Jacob F., Surer, Elif, Wootton, James, Yeh, Lia, Zabello, Olga, and Chiofalo, Marilù

Subjects

Physics - Physics Education, Physics - Physics and Society, Quantum Physics

Abstract

In this article, we provide an extensive overview of a wide range of quantum games and interactive tools that have been employed by the community in recent years. The paper presents selected tools, as described by their developers. The list includes Hello Quantum, Hello Qiskit, Particle in a Box, Psi and Delta, QPlayLearn, Virtual Lab by Quantum Flytrap, Quantum Odyssey, ScienceAtHome, and The Virtual Quantum Optics Laboratory. Additionally, we present events for quantum game development: hackathons, game jams, and semester projects. Furthermore, we discuss the Quantum Technologies Education for Everyone (QUTE4E) pilot project, which illustrates an effective integration of these interactive tools with quantum outreach and education activities. Finally, we aim at providing guidelines for incorporating quantum games and interactive tools in pedagogic materials to make quantum technologies more accessible for a wider population., Comment: 39 pages, 17 figures

Published

2022

10. Dynamical uncertainty propagation with noisy quantum parameters

Author

Dalgaard, Mogens, Weidner, Carrie A., and Motzoi, Felix

Subjects

Quantum Physics

Abstract

Many quantum technologies rely on high-precision dynamics, which raises the question of how these are influenced by the experimental uncertainties that are always present in real-life settings. A standard approach in the literature to assess this is Monte Carlo sampling, which suffers from two major drawbacks. First, it is computationally expensive. Second, it does not reveal the effect that each individual uncertainty parameter has on the state of the system. In this work, we evade both these drawbacks by incorporating propagation of uncertainty directly into simulations of quantum dynamics, thereby obtaining a method that is faster than Monte Carlo simulations and directly provides information on how each uncertainty parameter influence the system dynamics. Additionally, we compare our method to experimental results obtained using the IBM quantum computers., Comment: 10 pages, 3 figures

Published

2021

11. Anyon braiding on a fractal lattice with a local Hamiltonian

Author

Manna, Sourav, Duncan, Callum W., Weidner, Carrie A., Sherson, Jacob F., and Nielsen, Anne E. B.

Subjects

Condensed Matter - Quantum Gases, Condensed Matter - Strongly Correlated Electrons

Abstract

There is a growing interest in searching for topology in fractal dimensions with the aim of finding different properties and advantages compared to the integer dimensional case. It has previously been shown that the Laughlin state can be adapted to fractal lattices. A key element in doing so is to replace the uniform background charge by a background charge that resides only on the lattice sites. This motivates the study of Hofstadter type models on fractal lattices, in which the magnetic field is present only at the lattice sites. Here, we study such models for hardcore bosons on finite lattices derived from the Sierpinski carpet and on square lattices with open boundary conditions. We find that the system sizes that we can investigate with exact diagonalization are generally too small to judge whether these local models are topological or not. Studying the particle densities on the lattices derived from the Sierpinski carpet, we find that the densities tend to accumulate in the regions that are locally similar to a square lattice. Such accumulation seems to be incompatible with the uniform densities in fractional quantum Hall systems, which might suggest that the models are not topological. Our computations provide guidance for future searches for topology in finite systems. We also propose a scheme to implement both fractal lattices and our proposed local Hamiltonian with ultracold atoms in optical lattices, which could allow for quantum simulators to go beyond the numerical results presented here., Comment: 8 pages, 4 figures. The journal references below correspond to version v2. Version v3 is an updated version that takes the corrections in [Phys. Rev. A 107, 069901(E) (2023)] into account

Published

2021

12. Student use of a quantum simulation and visualization tool

Author

Ahmed, Shaeema Zaman, Weidner, Carrie A., Jensen, Jesper H. M., Sherson, Jacob F., and Lewandowski, H. J.

Subjects

Physics - Physics Education

Abstract

Knowledge of quantum mechanical systems is becoming more important for many science and engineering students who are looking to join the emerging quantum workforce. To better prepare a wide range of students for these careers, we must seek to develop new tools to enhance our education in quantum topics. We present initial studies on the use of one of these such tools, Quantum Composer, a 1D quantum simulation and visualization tool developed for education and research purposes. In particular, we conducted five think-aloud interviews with students who worked through an exercise using Quantum Composer that focused on the statics and dynamics of quantum states in a single harmonic well system. Our results show that Quantum Composer helps students to obtain the correct answers to the questions posed, but additional support is needed to facilitate the development of student reasoning behind these answers. We also show that students are able to focus only on the relevant features of Quantum Composer to achieve the task.

Published

2021

13. SciNote: Collaborative Problem Solving and Argumentation Tool

Author

Rafner, Janet, Hjorth, Arthur, Weidner, Carrie, Ahmed, Shaeema Zaman, Poulsen, Christian, Klokmose, Clemens, and Sherson, Jacob

Subjects

Computer Science - Computers and Society, Computer Science - Human-Computer Interaction

Abstract

As educators push for students to learn science by doing science, there is a need for computational scaffolding to assist students' evaluation of scientific evidence and argument building. In this paper, we present a pilot study of SciNote, a CSCL tool allowing educators to integrate third-party software into a flexible and collaborative workspace. We explore how SciNote enables teams to build data-driven arguments during inquiry-based learning activities., Comment: International Society of the Learning Sciences

Published

2021

14. A training programme for early-stage researchers that focuses on developing personal science outreach portfolios

Author

Ahmed, Shaeema Zaman, Hjorth, Arthur, Rafner, Janet Frances, Weidner, Carrie Ann, Kragh, Gitte, Jensen, Jesper Hasseriis Mohr, Bobroff, Julien, Nielsen, Kristian Hvidtfelt, and Sherson, Jacob Friis

Subjects

Physics - Physics Education, Physics - Popular Physics, Quantum Physics

Abstract

Development of outreach skills is critical for researchers when communicating their work to non-expert audiences. However, due to the lack of formal training, researchers are typically unaware of the benefits of outreach training and often under-prioritize outreach. We present a training programme conducted with an international network of PhD students in quantum physics, which focused on developing outreach skills and an understanding of the associated professional benefits by creating an outreach portfolio consisting of a range of implementable outreach products. We describe our approach, assess the impact, and provide a list of guidelines for designing similar programmes across scientific disciplines in the future., Comment: 14 figures, 3 tables

Published

2021

15. Robust Control Performance for Open Quantum Systems

Author

Schirmer, Sophie G., Langbein, Frank C., Weidner, Carrie A., and Jonckheere, Edmond

Subjects

Mathematics - Optimization and Control, Electrical Engineering and Systems Science - Systems and Control, Quantum Physics

Abstract

Robust performance of control schemes for open quantum systems is investigated under classical uncertainties in the generators of the dynamics and nonclassical uncertainties due to decoherence and initial state preparation errors. A formalism is developed to measure performance based on the transmission of a dynamic perturbation or initial state preparation error to the quantum state error. This makes it possible to apply tools from classical robust control such as structured singular value analysis. A difficulty arising from the singularity of the closed-loop Bloch equations for the quantum state is overcome by introducing the #-inversion lemma, a specialized version of the matrix inversion lemma. Under some conditions, this guarantees continuity of the structured singular value at s = 0. Additional difficulties occur when symmetry gives rise to multiple open-loop poles, which under symmetry-breaking unfold into single eigenvalues. The concepts are applied to systems subject to pure decoherence and a general dissipative system example of two qubits in a leaky cavity under laser driving fields and spontaneous emission. A nonclassical performance index, steady-state entanglement quantified by the concurrence, a nonlinear function of the system state, is introduced. Simulations confirm a conflict between entanglement, its log-sensitivity and stability margin under decoherence., Comment: 12 pages, 4 figures, 1 table, in press

Published

2020

16. Quantum Composer: A programmable quantum visualization and simulation tool for education and research

Author

Ahmed, Shaeema Zaman, Jensen, Jesper Hasseriis Mohr, Weidner, Carrie Ann, Sørensen, Jens Jakob, Mudrich, Marcel, and Sherson, Jacob Friis

Subjects

Physics - Physics Education, Quantum Physics

Abstract

Making quantum mechanical equations and concepts come to life through interactive simulation and visualization are commonplace for augmenting learning and teaching. However, graphical visualizations nearly always exhibit a set of hard-coded functionalities while corresponding text-based codes offer a higher degree of flexibility at the expense of steep learning curves or time investments. We introduce Quantum Composer, which allows the user to build, expand, or explore quantum mechanical simulations by interacting with graphically connectable nodes, each corresponding to a physical concept, mathematical operation, visualization, etc. Abstracting away numerical and programming details while at the same time retaining accessibility, emphasis on understanding, and rapid feedback mechanisms, we illustrate through a series of examples its open-ended applicability in both introductory and advanced quantum mechanics courses, student projects, and for visual exploration within research environments., Comment: 29 pages, 12 figures

Published

2020

17. Crowdsourcing human common sense for quantum control

Author

Jensen, Jesper Hasseriis Mohr, Gajdacz, Miroslav, Ahmed, Shaeema Zaman, Czarkowski, Jakub Herman, Weidner, Carrie, Rafner, Janet, Sørensen, Jens Jakob, Mølmer, Klaus, and Sherson, Jacob Friis

Subjects

Quantum Physics

Abstract

Citizen science methodologies have over the past decade been applied with great success to help solve highly complex numerical challenges. Here, we take early steps in the quantum physics arena by introducing a citizen science game, Quantum Moves 2, and compare the performance of different optimization methods across three different quantum optimal control problems of varying difficulty. Inside the game, players can apply a gradient-based algorithm (running locally on their device) to optimize their solutions and we find that these results perform roughly on par with the best of the tested standard optimization methods performed on a computer cluster. In addition, cluster-optimized player seeds was the only method to exhibit roughly optimal performance across all three challenges. This highlights the potential for crowdsourcing the solution of future quantum research problems., Comment: 15 figures

Published

2020

18. Spatial tomography of individual atoms in a quantum gas microscope

Author

Elíasson, Ottó, Laustsen, Jens S., Heck, Robert, Müller, Romain, Weidner, Carrie A., Arlt, Jan J., and Sherson, Jacob F.

Subjects

Condensed Matter - Quantum Gases, Quantum Physics

Abstract

We demonstrate a method to determine the position of single atoms in a three-dimensional optical lattice. Atoms are sparsely loaded from a far-off-resonant optical tweezer into a few vertical planes of a cubic optical lattice positioned near a high-resolution microscope objective. In a single realization of the experiment, we pin the atoms in deep lattices and then acquire multiple fluorescence images with single-site resolution. The objective is translated between images, bringing different lattice planes of the lattice into focus. The applicability of our method is assessed using simulated fluorescence images, where the atomic filling fraction in the lattice is varied. This opens up the possibility of extending the domain of quantum simulation using quantum gas microscopes from two to three dimensions., Comment: 8 pages, 5 figures

Published

2019

19. Deterministic generation of highly squeezed GKP states in ultracold atoms

Author

Kendell, Harry C. P., primary, Ferranti, Giacomo, additional, and Weidner, Carrie A., additional

Published

2024

20. Three-dimensional imaging of single atoms in an optical lattice via helical point-spread-function engineering

Author

Legrand, Tangi, primary, Winkelmann, Falk-Richard, additional, Alt, Wolfgang, additional, Meschede, Dieter, additional, Alberti, Andrea, additional, and Weidner, Carrie A., additional

Published

2024

21. Games for Quantum Physics Education

Author

Chiofalo, Maria Luisa (Marilù), primary, Foti, Caterina, additional, Lazzeroni, Cristina, additional, Maniscalco, Sabrina, additional, Seskir, Zeki C., additional, Sherson, Jacob, additional, Weidner, Carrie Ann, additional, and Michelini, Marisa, additional

Published

2024

22. Games for Quantum Physics Education

Author

Chiofalo, Maria Luisa, Foti, Caterina, Lazzeroni, Cristina, Maniscalco, Sabrina, Seskir, Zeki C., Sherson, Jacob, Weidner, Carrie Ann, Michelini, Marisa, Chiofalo, Maria Luisa, Foti, Caterina, Lazzeroni, Cristina, Maniscalco, Sabrina, Seskir, Zeki C., Sherson, Jacob, Weidner, Carrie Ann, and Michelini, Marisa

Abstract

As the second quantum revolution comes to pass with its potential to revolutionize our lives, it becomes increasingly relevant to educate the public about quantum mechanics. Quantum literacy is also a formidable challenge and opportunity for a massive cultural uplift, since it fosters the possibility for citizens to engender their creativity and practice a new way of thinking. However, quantum theory is highly counterintuitive, manifesting in a reality we have no direct experience of, and represented by mathematically difficult formalisms. Here, we propose that games can provide a playground for engaging forms of experimental and symbolic literacy accessible to anyone. We discuss the theoretical foundations underlying this idea in the framework of a global educational strategy, illustrate existing examples of its implementation along different dimensions related to educational, citizen-science, and age-related contexts, and envision future challenges., As the second quantum revolution comes to pass with its potential to revolutionize our lives, it becomes increasingly relevant to educate the public about quantum mechanics. Quantum literacy is also a formidable challenge and opportunity for a massive cultural uplift, since it fosters the possibility for citizens to engender their creativity and practice a new way of thinking. However, quantum theory is highly counterintuitive, manifesting in a reality we have no direct experience of, and represented by mathematically difficult formalisms. Here, we propose that games can provide a playground for engaging forms of experimental and symbolic literacy accessible to anyone. We discuss the theoretical foundations underlying this idea in the framework of a global educational strategy, illustrate existing examples of its implementation along different dimensions related to educational, citizen-science, and age-related contexts, and envision future challenges.

Published

2024

23. Experimental demonstration of classical Hamiltonian monodromy in the 1:1:2 resonant elastic pendulum

Author

Fitch, Noah J., Weidner, Carrie A., Parazzoli, L. Paul, Dullin, H. R., and Lewandowski, Heather J.

Subjects

Physics - Atomic Physics, Physics - Classical Physics

Abstract

The 1:1:2 resonant elastic pendulum is a simple classical system that displays the phenomenon known as Hamiltonian monodromy. With suitable initial conditions, the system oscillates between nearly pure springing and nearly pure elliptical-swinging motions, with sequential major axes displaying a stepwise precession. The physical consequence of monodromy is that this stepwise precession is given by a smooth but multivalued function of the constants of motion. We experimentally explore this multivalued behavior. To our knowledge, this is the first experimental demonstration of classical monodromy., Comment: 5 pages, accepted to PRL

Published

2009

24. Sample-efficient model-based reinforcement learning for quantum control

Author

Khalid, Irtaza, primary, Weidner, Carrie A., additional, Jonckheere, Edmond A., additional, Schirmer, Sophie G., additional, and Langbein, Frank C., additional

Published

2023

25. Erratum: Anyon braiding on a fractal lattice with a local Hamiltonian [Phys. Rev. A 105 , L021302 (2022)]

Author

Manna, Sourav, primary, Duncan, Callum W., additional, Weidner, Carrie A., additional, Sherson, Jacob F., additional, and Nielsen, Anne E. B., additional

Published

2023

26. Statistically characterizing robustness and fidelity of quantum controls and quantum control algorithms

Author

Khalid, Irtaza, primary, Weidner, Carrie A., additional, Jonckheere, Edmond A., additional, Shermer, Sophie G., additional, and Langbein, Frank C., additional

Published

2023

27. Time-Domain Sensitivity of the Tracking Error

Author

O'Neil, Sean, Schirmer, Sophie, Langbein, Frank C., Weidner, Carrie A., and Jonckheere, Edmond A.

Abstract

A strictly time-domain. formulation of the log-sensitivity of the error signal to structured plant uncertainty is presented and analyzed through simple but representative classical and quantum systems. Results demonstrate that across a wide range of physical systems, maximization of performance (minimization of the error signal) asymptotically or at a specific time comes at the cost of increased log-sensitivity, implying a time-domain constraint analogous to the frequency-domain identity $\mathbf {S(s) + T(s) = I}$. While of limited value in classical problems based on asymptotic stabilization or tracking, such a time-domain formulation is valuable in assessing the reduced robustness cost concomitant with high-fidelity quantum control schemes predicated on time-based performance measures.

Published

2024

28. Robust Control Performance for Open Quantum Systems

Author

Schirmer, Sophie G., primary, Langbein, Frank C., additional, Weidner, Carrie Ann, additional, and Jonckheere, Edmond, additional

Published

2022

29. Student use of a quantum simulation and visualization tool

Author

Zaman Ahmed, Shaeema, primary, Weidner, Carrie A, additional, Jensen, Jesper H M, additional, Sherson, Jacob F, additional, and Lewandowski, H J, additional

Published

2022

30. Direct measurement of the Wigner function of atoms in an optical trap

Author

Winkelmann, Falk-Richard, primary, Weidner, Carrie A, additional, Ramola, Gautam, additional, Alt, Wolfgang, additional, Meschede, Dieter, additional, and Alberti, Andrea, additional

Published

2022

31. Quantum games and interactive tools for quantum technologies outreach and education

Author

Seskir, Zeki C., primary, Migdał, Piotr, additional, Weidner, Carrie, additional, Anupam, Aditya, additional, Case, Nicky, additional, Davis, Noah, additional, Decaroli, Chiara, additional, Ercan, İlke, additional, Foti, Caterina, additional, Gora, Paweł, additional, Jankiewicz, Klementyna, additional, La Cour, Brian R., additional, Yago Malo, Jorge, additional, Maniscalco, Sabrina, additional, Naeemi, Azad, additional, Nita, Laurentiu, additional, Parvin, Nassim, additional, Scafirimuto, Fabio, additional, Sherson, Jacob F., additional, Surer, Elif, additional, Wootton, James, additional, Yeh, Lia, additional, Zabello, Olga, additional, and Chiofalo, Marilù, additional

Published

2022

32. Quantum games and interactive tools for quantum technologies outreach and education

Author

Seskir, Zeki C. (author), Migdał, Piotr (author), Weidner, Carrie (author), Anupam, Aditya (author), Case, Nicky (author), Davis, Noah (author), Decaroli, Chiara (author), Ercan, İlke (author), Foti, Caterina (author), Seskir, Zeki C. (author), Migdał, Piotr (author), Weidner, Carrie (author), Anupam, Aditya (author), Case, Nicky (author), Davis, Noah (author), Decaroli, Chiara (author), Ercan, İlke (author), and Foti, Caterina (author)

Abstract

We provide an extensive overview of a wide range of quantum games and interactive tools that have been employed by the quantum community in recent years. We present selected tools as described by their developers, including "Hello Quantum, Hello Qiskit, Particle in a Box, Psi and Delta, QPlayLearn, Virtual Lab by Quantum Flytrap, Quantum Odyssey, ScienceAtHome, and the Virtual Quantum Optics Laboratory."In addition, we present events for quantum game development: hackathons, game jams, and semester projects. Furthermore, we discuss the Quantum Technologies Education for Everyone (QUTE4E) pilot project, which illustrates an effective integration of these interactive tools with quantum outreach and education activities. Finally, we aim at providing guidelines for incorporating quantum games and interactive tools in pedagogic materials to make quantum technologies more accessible for a wider population., Green Open Access added to TU Delft Institutional Repository ‘You share, we take care!’ – Taverne project https://www.openaccess.nl/en/you-share-we-take-care Otherwise as indicated in the copyright section: the publisher is the copyright holder of this work and the author uses the Dutch legislation to make this work public., Microelectronics, Electrical Engineering Education

Published

2022

33. Is certification for pharmaceutical sales representatives necessary?

Author

Alkhateeb, Fadi M., Baidoo, Patricia, Mikulskis Cavana, Marija, Gill, Danielle, Howell, Amanda, Mehraeen, Babak, and Weidner, Carrie

Published

2011

34. Dynamical Uncertainty Propagation with Noisy Quantum Parameters

Author

Dalgaard, Mogens, primary, Weidner, Carrie A., additional, and Motzoi, Felix, additional

Published

2022

35. Anyon braiding on a fractal lattice with a local Hamiltonian

Author

Manna, Sourav, primary, Duncan, Callum W., additional, Weidner, Carrie A., additional, Sherson, Jacob F., additional, and Nielsen, Anne E. B., additional

Published

2022

36. Student engagement and learning with Quantum Composer

Author

Ahmed, Shaeema Zaman, Weidner, Carrie Ann, Jensen, Jesper Hasseriis Mohr, Sherson, Jacob, and Lewandowski, Heather J.

Subjects

ComputingMilieux_COMPUTERSANDEDUCATION

Abstract

Knowledge of quantum mechanical systems is becoming more important for many science and engineering students who are looking to join the emerging quantum workforce. To better prepare a wide range of students for these careers, we must seek to develop new tools to enhance our education in quantum topics. We present initial studies on the use of one of these such tools, Quantum Composer, a 1D quantum simulation and visualization tool developed for education and research purposes. In particular, we conducted five think-aloud interviews with students who worked through an exercise using Quantum Composer that focused on the statics and dynamics of quantum states in single- and double-harmonic well systems. Our results show that Quantum Composer helps students to obtain the correct answers to the questions posed, but additional support is needed to facilitate the development of student reasoning behind these answers. In addition, we find that students explore familiar and unfamiliar problems in similar ways, indicating that Quantum Composer is a useful tool for exploring systems that students have not seen before.

Published

2021

37. Quantum composer: A programmable quantum visualization and simulation tool for education and research

Author

Zaman Ahmed, Shaeema, primary, Jensen, Jesper Hasseriis Mohr, additional, Weidner, Carrie Ann, additional, Sørensen, Jens Jakob, additional, Mudrich, Marcel, additional, and Sherson, Jacob Friis, additional

Published

2021

38. Crowdsourcing human common sense for quantum control

Author

Jensen, Jesper Hasseriis Mohr, primary, Gajdacz, Miroslav, additional, Ahmed, Shaeema Zaman, additional, Czarkowski, Jakub Herman, additional, Weidner, Carrie, additional, Rafner, Janet, additional, Sørensen, Jens Jakob, additional, Mølmer, Klaus, additional, and Sherson, Jacob Friis, additional

Published

2021

39. Spatial tomography of individual atoms in a quantum gas microscope

Author

Elíasson, Ottó, primary, Laustsen, Jens S., additional, Heck, Robert, additional, Müller, Romain, additional, Arlt, Jan J., additional, Weidner, Carrie A., additional, and Sherson, Jacob F., additional

Published

2020

40. Investigating student use of a flexible tool for simulating and visualizing quantum mechanics

Author

Weidner, Carrie A., primary, Ahmed, Shaeema Z., additional, Jensen, Jesper H. M., additional, Sherson, Jacob F., additional, and Lewandowski, H. J., additional

Published

2020

41. A man-machine mind meld for quantum computing: Can an online game that combines human brainpower with AI solve intractable problems?

Author

Eliasson, Otto, primary, Weidner, Carrie, additional, Rafner, Janet, additional, and Ahmed, Shaeema Zaman, additional

Published

2019

42. Building an inclusive community.

Author

Belsley, Alex, Radulovic, Marija, Stephen, Angela, and Weidner, Carrie

Published

2023

43. Applying classical control techniques to quantum systems: entanglement versus stability margin and other limitations

Author

Weidner, Carrie A., Schirmer, Sophie G., Langbein, Frank C., Jonckheere, Edmond, Weidner, Carrie A., Schirmer, Sophie G., Langbein, Frank C., and Jonckheere, Edmond

Abstract

Development of robust quantum control has been challenging and there are numerous obstacles to applying classical robust control to quantum system including bilinearity, marginal stability, state preparation errors, nonlinear figures of merit. The requirement of marginal stability, while not satisfied for closed quantum systems, can be satisfied for open quantum systems where Lindbladian behavior leads to non-unitary evolution, and allows for nonzero classical stability margins, but it remains difficult to extract physical insight when classical robust control tools are applied to these systems. We consider a straightforward example of the entanglement between two qubits dissipatively coupled to a lossy cavity and analyze it using the classical stability margin and structured perturbations. We attempt, where possible, to extract physical insight from these analyses. Our aim is to highlight where classical robust control can assist in the analysis of quantum systems and identify areas where more work needs to be done to develop specific methods for quantum robust control.