Related papers: Gaussian boson sampling for binary optimization

Gaussian boson sampling for binary optimization

URL: http://arxiv.org/abs/2412.14783v1
Date: Thu, 19 Dec 2024 12:12:22 GMT
Title: Gaussian boson sampling for binary optimization
Authors: Jean Cazalis, Tirth Shah, Yahui Chai, Karl Jansen, Stefan Kühn,
Abstract summary: We propose to use a parametrized Gaussian Boson Sampler (GBS) with threshold detectors to address binary optimization problems. Numerical experiments on 3-SAT and Graphing problems show significant performance gains over random guessing.
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Abstract: Binary optimization is a fundamental area in computational science, with wide-ranging applications from logistics to cryptography, where the tasks are often formulated as Quadratic or Polynomial Unconstrained Binary Optimization problems (QUBO/PUBO). In this work, we propose to use a parametrized Gaussian Boson Sampler (GBS) with threshold detectors to address such problems. We map general PUBO instance onto a quantum Hamiltonian and optimize the Conditional Value-at-Risk of its energy with respect to the GBS ansatz. In particular, we observe that, when the algorithm reduces to standard Variational Quantum Eigensolver, the cost function is analytical. Therefore, it can be computed efficiently, along with its gradient, for low-degree polynomials using only classical computing resources. Numerical experiments on 3-SAT and Graph Partitioning problems show significant performance gains over random guessing, providing a first proof of concept for our proposed approach.

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