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1. Warm-Starting and Quantum Computing: A Systematic Mapping Study

Author

Truger, Felix, Barzen, Johanna, Bechtold, Marvin, Beisel, Martin, Leymann, Frank, Mandl, Alexander, and Yussupov, Vladimir

Subjects
Quantum Physics
Abstract

Due to low numbers of qubits and their error-proneness, Noisy Intermediate-Scale Quantum (NISQ) computers impose constraints on the size of quantum algorithms they can successfully execute. State-of-the-art research introduces various techniques addressing these limitations by utilizing known or inexpensively generated approximations, solutions, or models as a starting point to approach a task instead of starting from scratch. These so-called warm-starting techniques aim to reduce quantum resource consumption, thus facilitating the design of algorithms suiting the capabilities of NISQ computers. In this work, we collect and analyze scientific literature on warm-starting techniques in the quantum computing domain. In particular, we (i) create a systematic map of state-of-the-art research on warm-starting techniques using established guidelines for systematic mapping studies, (ii) identify relevant properties of such techniques, and (iii) based on these properties classify the techniques identified in the literature in an extensible classification scheme. Our results provide insights into the research field and aim to help quantum software engineers to categorize warm-starting techniques and apply them in practice. Moreover, our contributions may serve as a starting point for further research on the warm-starting topic since they provide an overview of existing work and facilitate the identification of research gaps., Comment: 29 pages, 8 figures, 5 tables, This is the authors' version of the work. It is posted here for your personal use. Not for redistribution. The definitive version was published in ACM Computing Surveys, https://doi.org/10.1145/3652510

Published
2023
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4. Configurable Readout Error Mitigation in Quantum Workflows.

Author

Beisel, Martin, Barzen, Johanna, Leymann, Frank, Truger, Felix, Weder, Benjamin, and Yussupov, Vladimir

Subjects
MEASUREMENT errors, QUANTUM computers, QUANTUM computing, WORKFLOW
Abstract

Current quantum computers are still error-prone, with measurement errors being one of the factors limiting the scalability of quantum devices. To reduce their impact, a variety of readout error mitigation methods, mostly relying on classical post-processing, have been developed. However, the application of these methods is complicated by their heterogeneity and a lack of information regarding their functionality, configuration, and integration. To facilitate their use, we provide an overview of existing methods, and evaluate general and method-specific configuration options. Quantum applications comprise many classical pre- and post-processing tasks, including readout error mitigation. Automation can facilitate the execution of these often complex tasks, as their manual execution is time-consuming and error-prone. Workflow technology is a promising candidate for the orchestration of heterogeneous tasks, offering advantages such as reliability, robustness, and monitoring capabilities. In this paper, we present an approach to abstractly model quantum workflows comprising configurable readout error mitigation tasks. Based on the method configuration, these workflows can then be automatically refined into executable workflow models. To validate the feasibility of our approach, we provide a prototypical implementation and demonstrate it in a case study from the quantum humanities domain. [ABSTRACT FROM AUTHOR]

Published
2022
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5. Selection and Optimization of Hyperparameters in Warm-Started Quantum Optimization for the MaxCut Problem.

Author

Truger, Felix, Beisel, Martin, Barzen, Johanna, Leymann, Frank, and Yussupov, Vladimir

Subjects
CIRCUIT complexity, REGULARIZATION parameter, QUANTUM computing, CUTTING stock problem, QUANTUM computers, MATHEMATICAL optimization
Abstract

Today's quantum computers are limited in their capabilities, e.g., the size of executable quantum circuits. The Quantum Approximate Optimization Algorithm (QAOA) addresses these limitations and is, therefore, a promising candidate for achieving a near-term quantum advantage. Warm-starting can further improve QAOA by utilizing classically pre-computed approximations to achieve better solutions at a small circuit depth. However, warm-starting requirements often depend on the quantum algorithm and problem at hand. Warm-started QAOA (WS-QAOA) requires developers to understand how to select approach-specific hyperparameter values that tune the embedding of classically pre-computed approximations. In this paper, we address the problem of hyperparameter selection in WS-QAOA for the maximum cut problem using the classical Goemans–Williamson algorithm for pre-computations. The contributions of this work are as follows: We implement and run a set of experiments to determine how different hyperparameter settings influence the solution quality. In particular, we (i) analyze how the regularization parameter that tunes the bias of the warm-started quantum algorithm towards the pre-computed solution can be selected and optimized, (ii) compare three distinct optimization strategies, and (iii) evaluate five objective functions for the classical optimization, two of which we introduce specifically for our scenario. The experimental results provide insights on efficient selection of the regularization parameter, optimization strategy, and objective function and, thus, support developers in setting up one of the central algorithms of contemporary and near-term quantum computing. [ABSTRACT FROM AUTHOR]

Published
2022
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