Garden optimization problems for benchmarking quantum annealers

Calaza, Carlos D. Gonzalez; Willsch, Dennis; Michielsen, Kristel

doi:10.1007/s11128-021-03226-6

Cited by 15 publications

(4 citation statements)

References 29 publications

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“…Obviously, the energy gap between the ground state and the excited state is much smaller for the Advantage_system4.1 annealing schedule, which means the G 1 problem is then harder to solve, resulting in the longer annealing times required to achieve the same success probabilities as with the other annealing schedules. This might be different for other problems but especially for small and/or sparse problems, it was observed that DW_2000Q processors could achieve a better performance than Advantage processors (Calaza et al, 2021;Willsch et al, 2022a).…”

Section: (Ideal) Quantum Annealing Simulation Influence Of the Anne...mentioning

confidence: 97%

“…Previous studies compared D-Wave 2000Q and Advantage system (Calaza et al, 2021;McLeod and Sasdelli, 2022;Willsch et al, 2022a), D-Wave 2000Q, Advantage system and Advantage2 prototype (Pelofske, 2023), and D-Wave Two, D-Wave 2X, D-Wave 2000Q, and Advantage system (Pokharel et al, 2021). (iii) Another aspect is the search for quantum speedup (Rønnow et al, 2014) and investigations of the performance of quantum processors in comparison to classical algorithms.…”

Section: Introductionmentioning

confidence: 99%

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Benchmarking quantum annealing with maximum cardinality matching problems

Vert,

Willsch,

Yenilen

et al. 2024

Front. Comput. Sci.

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We benchmark Quantum Annealing (QA) vs. Simulated Annealing (SA) with a focus on the impact of the embedding of problems onto the different topologies of the D-Wave quantum annealers. The series of problems we study are especially designed instances of the maximum cardinality matching problem that are easy to solve classically but difficult for SA and, as found experimentally, not easy for QA either. In addition to using several D-Wave processors, we simulate the QA process by numerically solving the time-dependent Schrödinger equation. We find that the embedded problems can be significantly more difficult than the unembedded problems, and some parameters, such as the chain strength, can be very impactful for finding the optimal solution. Thus, finding a good embedding and optimal parameter values can improve the results considerably. Interestingly, we find that although SA succeeds for the unembedded problems, the SA results obtained for the embedded version scale quite poorly in comparison with what we can achieve on the D-Wave quantum annealers.

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Section: (Ideal) Quantum Annealing Simulation Influence Of the Anne...mentioning

confidence: 97%

Section: Introductionmentioning

confidence: 99%

Benchmarking quantum annealing with maximum cardinality matching problems

Vert,

Willsch,

Yenilen

et al. 2024

Front. Comput. Sci.

Self Cite

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“…An important category of optimization problems is optimal placement. In this context, an interesting real-world application is garden optimization [61], whose target is to optimally place n plants in n pots (as shown in Figure 5d). This problem can be written in QUBO formulation with n 2 binary variables, one for each plant-pot pair.…”

Section: D: Garden Optimizationmentioning

confidence: 99%

Integration of Simulated Quantum Annealing in Parallel Tempering and Population Annealing for Heterogeneous-Profile QUBO Exploration

et al. 2023

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Simulated Quantum Annealing (SQA) is a heuristic algorithm which can solve Quadratic Unconstrained Binary Optimization (QUBO) problems by emulating the exploration of the solution space done by a quantum annealer. It mimics the quantum superposition and tunnelling effects through a set of correlated replicas of the spins system representing the problem to be solved and performing Monte Carlo steps. However, the effectiveness of SQA over a classical algorithm strictly depends on the cost/energy profile of the target problem. In fact, quantum annealing only performs well in exploring functions with high and narrow peaks, while classical annealing is better in overcoming flat and wide energy-profile barriers. Unfortunately, real-world problems have a heterogeneous solution space and the probability of success of each solver depends on the size of the energy profile region compatible with its exploration mechanism. Therefore, significant advantages could be obtained by exploiting hybrid solvers, which combine SQA and classical algorithms. This work proposes four new quantum-classical algorithms: Simulated Quantum Parallel Tempering (SQPT), Simulated Quantum Population Annealing (SQPA), Simulated Quantum Parallel Tempering -Population Annealing v1 (SQPTPA1) and Simulated Quantum Parallel Tempering -Population Annealing v2 (SQPTPA2). They are obtained by combining SQA, Parallel Tempering (PT), and Population Annealing (PA). Their results are compared with those provided by SQA, considering benchmark QUBO problems, characterized by different profiles. Even though this work is preliminary, the obtained results are encouraging and prove hybrid solvers' potential in solving a generic optimization problem.

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“…A reasonable starting point for optimizing the chain strength is to set it to the largest coupling strength of the original QUBO problem [38]. We define the relative chain strength (RCS) as…”

Section: B Qubit Chainsmentioning

confidence: 99%

Quantum Annealing for Jet Clustering with Thrust

Delgado¹,

Thaler²

2022

Preprint

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Quantum computing holds the promise of substantially speeding up computationally expensive tasks, such as solving optimization problems over a large number of elements. In high-energy collider physics, quantum-assisted algorithms might accelerate the clustering of particles into jets. In this study, we benchmark quantum annealing strategies for jet clustering based on optimizing a quantity called "thrust" in electron-positron collision events. We find that quantum annealing yields similar performance to exact classical approaches and classical heuristics, but only after tuning the annealing parameters. Without tuning, comparable performance can be obtained through a hybrid quantum/classical approach.

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Garden optimization problems for benchmarking quantum annealers

Cited by 15 publications

References 29 publications

Benchmarking quantum annealing with maximum cardinality matching problems

Benchmarking quantum annealing with maximum cardinality matching problems

Integration of Simulated Quantum Annealing in Parallel Tempering and Population Annealing for Heterogeneous-Profile QUBO Exploration

Quantum Annealing for Jet Clustering with Thrust

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