Bias-Field Digitized Counterdiabatic Quantum Algorithm for Higher-Order Binary Optimization
- URL: http://arxiv.org/abs/2409.04477v2
- Date: Sun, 24 Aug 2025 16:59:38 GMT
- Title: Bias-Field Digitized Counterdiabatic Quantum Algorithm for Higher-Order Binary Optimization
- Authors: Sebastián V. Romero, Anne-Maria Visuri, Alejandro Gomez Cadavid, Anton Simen, Enrique Solano, Narendra N. Hegade,
- Abstract summary: Combinatorial optimization plays a crucial role in many industrial applications.<n>We present an enhanced bias-field digitized counterdiabatic quantum optimization (BF-DCQO) algorithm to address higher-order unconstrained binary optimization (HUBO)<n>Our results show that BF-DCQO offers an effective path for solving large-scale HUBO problems on current and near-term quantum processors.
- Score: 35.18016233072556
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Combinatorial optimization plays a crucial role in many industrial applications. While classical computing often struggles with complex instances, quantum optimization emerges as a promising alternative. Here, we present an enhanced bias-field digitized counterdiabatic quantum optimization (BF-DCQO) algorithm to address higher-order unconstrained binary optimization (HUBO). We apply BF-DCQO to a HUBO problem featuring three-local terms in the Ising spin-glass model, validated experimentally using 156 qubits on an IBM quantum processor. In the studied instances, our results outperform standard methods such as the quantum approximate optimization algorithm, quantum annealing, simulated annealing, and Tabu search. Furthermore, we provide numerical evidence of the feasibility of a similar HUBO problem on a 433-qubit Osprey-like quantum processor. Finally, we solve denser instances of the MAX 3-SAT problem in an IonQ emulator. Our results show that BF-DCQO offers an effective path for solving large-scale HUBO problems on current and near-term quantum processors.
Related papers
- Runtime Quantum Advantage with Digital Quantum Optimization [36.136619420474766]
bias-field digitized counterdiabatic quantum optimization (BF-DCQO) algorithm on IBM's 156-qubit devices.<n>We suitably select problem instances that are challenging for classical methods, running in fractions of minutes even with multicore processors.<n>Our results indicate that available digital quantum processors, when combined with specific-purpose quantum algorithms, exhibit a runtime quantum advantage even in the absence of quantum error correction.
arXiv Detail & Related papers (2025-05-13T15:24:17Z) - Branch-and-bound digitized counterdiabatic quantum optimization [39.58317527488534]
Branch-and-bound algorithms effectively solve convex optimization problems, relying on the relaxation the objective function to obtain tight lower bounds.
We propose a branch-and-bound digitized counterdiabatic quantum optimization (BB-DCQO) algorithm that addresses the relaxation difficulties.
arXiv Detail & Related papers (2025-04-21T18:19:19Z) - Boosting quantum annealing performance through direct polynomial unconstrained binary optimization [0.0]
We show how PUBO formulation can bring considerable savings in terms of required number of qubits.<n>We find scenarios where the scaling of the minimum energy gap during the optimization sweep differs significantly.<n>As an interesting side effect, the analysis on minimum energy gaps of different 3-SAT instance generators reveals different degrees of hardness.
arXiv Detail & Related papers (2024-12-05T18:12:20Z) - Bias-field digitized counterdiabatic quantum optimization [39.58317527488534]
We call this protocol bias-field digitizeddiabatic quantum optimization (BF-DCQO)
Our purely quantum approach eliminates the dependency on classical variational quantum algorithms.
It achieves scaling improvements in ground state success probabilities, increasing by up to two orders of magnitude.
arXiv Detail & Related papers (2024-05-22T18:11:42Z) - Performance analysis of a filtering variational quantum algorithm [0.0]
Filtering Variational Quantum Eigensolver (F-VQE) is a variational hybrid quantum algorithm designed to solve optimization problems on existing quantum computers.
We employ Instantaneous Quantum Polynomial circuits as our parameterized quantum circuits.
Despite some observed positive signs, we conclude that significant development is necessary for a practical advantage with F-VQE.
arXiv Detail & Related papers (2024-04-13T08:50:44Z) - Unlocking Quantum Optimization: A Use Case Study on NISQ Systems [0.0]
This paper considers two industrial relevant use cases: one in the realm of optimizing charging schedules for electric vehicles, the other concerned with the optimization of truck routes.
Our central contribution are systematic series of examples derived from these uses cases that we execute on different processors of the gate-based quantum computers of IBM as well as on the quantum annealer of D-Wave.
arXiv Detail & Related papers (2024-04-10T17:08:07Z) - Qubit efficient quantum algorithms for the vehicle routing problem on
NISQ processors [48.68474702382697]
Vehicle routing problem with time windows (VRPTW) is a common optimization problem faced within the logistics industry.
In this work, we explore the use of a previously-introduced qubit encoding scheme to reduce the number of binary variables.
arXiv Detail & Related papers (2023-06-14T13:44:35Z) - Quantum Annealing for Single Image Super-Resolution [86.69338893753886]
We propose a quantum computing-based algorithm to solve the single image super-resolution (SISR) problem.
The proposed AQC-based algorithm is demonstrated to achieve improved speed-up over a classical analog while maintaining comparable SISR accuracy.
arXiv Detail & Related papers (2023-04-18T11:57:15Z) - Trainable Variational Quantum-Multiblock ADMM Algorithm for Generation
Scheduling [0.0]
This paper proposes a two-loop quantum solution algorithm for generation scheduling by quantum computing, machine learning, and distributed optimization.
The aim is to facilitate noisy employing near-term quantum machines with a limited number of qubits to solve practical power system problems.
arXiv Detail & Related papers (2023-03-28T21:31:39Z) - Quantum Robustness Verification: A Hybrid Quantum-Classical Neural
Network Certification Algorithm [1.439946676159516]
In this work, we investigate the verification of ReLU networks, which involves solving a robustness many-variable mixed-integer programs (MIPs)
To alleviate this issue, we propose to use QC for neural network verification and introduce a hybrid quantum procedure to compute provable certificates.
We show that, in a simulated environment, our certificate is sound, and provide bounds on the minimum number of qubits necessary to approximate the problem.
arXiv Detail & Related papers (2022-05-02T13:23:56Z) - Adiabatic Quantum Computing for Multi Object Tracking [170.8716555363907]
Multi-Object Tracking (MOT) is most often approached in the tracking-by-detection paradigm, where object detections are associated through time.
As these optimization problems are often NP-hard, they can only be solved exactly for small instances on current hardware.
We show that our approach is competitive compared with state-of-the-art optimization-based approaches, even when using of-the-shelf integer programming solvers.
arXiv Detail & Related papers (2022-02-17T18:59:20Z) - Adiabatic Quantum Graph Matching with Permutation Matrix Constraints [75.88678895180189]
Matching problems on 3D shapes and images are frequently formulated as quadratic assignment problems (QAPs) with permutation matrix constraints, which are NP-hard.
We propose several reformulations of QAPs as unconstrained problems suitable for efficient execution on quantum hardware.
The proposed algorithm has the potential to scale to higher dimensions on future quantum computing architectures.
arXiv Detail & Related papers (2021-07-08T17:59:55Z) - Variational Quantum Optimization with Multi-Basis Encodings [62.72309460291971]
We introduce a new variational quantum algorithm that benefits from two innovations: multi-basis graph complexity and nonlinear activation functions.
Our results in increased optimization performance, two increase in effective landscapes and a reduction in measurement progress.
arXiv Detail & Related papers (2021-06-24T20:16:02Z) - Accelerating variational quantum algorithms with multiple quantum
processors [78.36566711543476]
Variational quantum algorithms (VQAs) have the potential of utilizing near-term quantum machines to gain certain computational advantages.
Modern VQAs suffer from cumbersome computational overhead, hampered by the tradition of employing a solitary quantum processor to handle large data.
Here we devise an efficient distributed optimization scheme, called QUDIO, to address this issue.
arXiv Detail & Related papers (2021-06-24T08:18:42Z) - Space-efficient binary optimization for variational computing [68.8204255655161]
We show that it is possible to greatly reduce the number of qubits needed for the Traveling Salesman Problem.
We also propose encoding schemes which smoothly interpolate between the qubit-efficient and the circuit depth-efficient models.
arXiv Detail & Related papers (2020-09-15T18:17:27Z) - Compilation of Fault-Tolerant Quantum Heuristics for Combinatorial
Optimization [0.14755786263360526]
We explore which quantum algorithms for optimization might be most practical to try out on a small fault-tolerant quantum computer.
Our results discourage the notion that any quantum optimization realizing only a quadratic speedup will achieve an advantage over classical algorithms.
arXiv Detail & Related papers (2020-07-14T22:54:04Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.