Machine Learning for Long-Distance Quantum Communication

Wallnöfer, Julius; Melnikov, A. A.; Dür, W.; Briegel, Hans J.

doi:10.1103/prxquantum.1.010301

Cited by 86 publications

(54 citation statements)

References 56 publications

(83 reference statements)

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“…We have introduced a methodology for the optimization of entanglement generation and distribution in repeater chains using GAs. In contrast with previous work in this area [18][19][20][21][22], our methodology is systematic, modular and broadly applicable. We validated it by benchmarking our GAs on functions commonly used for this purpose and by applying it to a repeater chain generating Werner states.…”

Section: Discussionmentioning

confidence: 99%

“…This allows us to answer questions such as what are the worst possible repeaters satisfying target benchmarks. Contrasting with previous work on repeater chain optimization [18][19][20][21][22][23], our methodology constitutes a systematic and modular approach to this problem, successfully integrating simulation and optimization tools, as well as allowing for the use of high-performance computing (HPC) clusters. A high-level overview of how a user interfaces with this process is shown in figure 1.…”

Section: Introductionmentioning

confidence: 99%

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Optimizing entanglement generation and distribution using genetic algorithms

Silva

Torres‐Knoop

Coopmans

et al. 2021

Quantum Sci. Technol.

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Long-distance quantum communication via entanglement distribution is of great importance for the quantum internet. However, scaling up to such long distances has proved challenging due to the loss of photons, which grows exponentially with the distance covered. Quantum repeaters could in theory be used to extend the distances over which entanglement can be distributed, but in practice hardware quality is still lacking. Furthermore, it is generally not clear how an improvement in a certain repeater parameter, such as memory quality or attempt rate, impacts the overall network performance, rendering the path toward scalable quantum repeaters unclear. In this work we propose a methodology based on genetic algorithms and simulations of quantum repeater chains for optimization of entanglement generation and distribution. By applying it to simulations of several different repeater chains, including real-world fiber topology, we demonstrate that it can be used to answer questions such as what are the minimum viable quantum repeaters satisfying given network performance benchmarks. This methodology constitutes an invaluable tool for the development of a blueprint for a pan-European quantum internet. We have made our code, in the form of NetSquid simulations and the smart-stopos optimization tool, freely available for use either locally or on high-performance computing centers.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Optimizing entanglement generation and distribution using genetic algorithms

Silva

Torres‐Knoop

Coopmans

et al. 2021

Quantum Sci. Technol.

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“…At present, due to various technological limitations, the use of quantum communication channels in large-scale complex networks is minimal; see Table 1 . Quantum communication networks, which are currently starting to implement classical AIA facilities, generally are realized at the principle of proofs level [ 95 ]. Their complexity and capabilities are not yet known in detail [ 96 ].…”

Section: State Of the Artmentioning

confidence: 99%

Emerging Complexity in Distributed Intelligent Systems

Guleva

Shikov

Bochenina

et al. 2020

Entropy

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Distributed intelligent systems (DIS) appear where natural intelligence agents (humans) and artificial intelligence agents (algorithms) interact, exchanging data and decisions and learning how to evolve toward a better quality of solutions. The networked dynamics of distributed natural and artificial intelligence agents leads to emerging complexity different from the ones observed before. In this study, we review and systematize different approaches in the distributed intelligence field, including the quantum domain. A definition and mathematical model of DIS (as a new class of systems) and its components, including a general model of DIS dynamics, are introduced. In particular, the suggested new model of DIS contains both natural (humans) and artificial (computer programs, chatbots, etc.) intelligence agents, which take into account their interactions and communications. We present the case study of domain-oriented DIS based on different agents’ classes and show that DIS dynamics shows complexity effects observed in other well-studied complex systems. We examine our model by means of the platform of personal self-adaptive educational assistants (avatars), especially designed in our University. Avatars interact with each other and with their owners. Our experiment allows finding an answer to the vital question: How quickly will DIS adapt to owners’ preferences so that they are satisfied? We introduce and examine in detail learning time as a function of network topology. We have shown that DIS has an intrinsic source of complexity that needs to be addressed while developing predictable and trustworthy systems of natural and artificial intelligence agents. Remarkably, our research and findings promoted the improvement of the educational process at our university in the presence of COVID-19 pandemic conditions.

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“…The rise of VQE has launched further development of variational quantum algorithms (VQAs) [67][68][69][70][71], targeting generic data analysis and machine learning tasks. Performed by parametrized quantum circuits, also dubbed as quantum neural networks (QNNs) [67], VQAs rapidly expand applications to include classification [72][73][74][75][76][77][78], regression [73], generative modeling [79][80][81][82][83][84][85][86][87], clustering [88,89], reinforcement learning [90][91][92][93][94][95], quantum simulation [96][97][98][99], quantum metrology [100][101][102], and other tasks. The power of VQAs for machine learning (ML) tasks comes from the high expressibility of quantum circuits, where data points are mapped to quantum states.…”

Section: Introductionmentioning

confidence: 99%

Solving nonlinear differential equations with differentiable quantum circuits

2021

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We propose a quantum algorithm to solve systems of nonlinear differential equations. Using a quantum feature map encoding, we define functions as expectation values of parametrized quantum circuits. We use automatic differentiation to represent function derivatives in an analytical form as differentiable quantum circuits (DQCs), thus avoiding inaccurate finite difference procedures for calculating gradients. We describe a hybrid quantum-classical workflow where DQCs are trained to satisfy differential equations and specified boundary conditions. As a particular example setting, we show how this approach can implement a spectral method for solving differential equations in a high-dimensional feature space. From a technical perspective, we design a Chebyshev quantum feature map that offers a powerful basis set of fitting polynomials and possesses rich expressivity. We simulate the algorithm to solve an instance of Navier-Stokes equations and compute density, temperature, and velocity profiles for the fluid flow in a convergent-divergent nozzle.

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Machine Learning for Long-Distance Quantum Communication

Cited by 86 publications

References 56 publications

Optimizing entanglement generation and distribution using genetic algorithms

Optimizing entanglement generation and distribution using genetic algorithms

Emerging Complexity in Distributed Intelligent Systems

Solving nonlinear differential equations with differentiable quantum circuits

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