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Bosonic Continuous Variable Quantum Computing Quantum Optimization

Symplectic Optimization on Gaussian States

arXiv

Authors: Christopher Willby, Tomohiro Hashizume, Jason Crain, Dieter Jaksch

Year

2026

Paper ID

3187

Status

Preprint

Abstract Read

~2 min

Abstract Words

156

Citations

N/A

Abstract

Computing Gaussian ground states via variational optimization is challenging because the covariance matrices must satisfy the uncertainty principle, rendering constrained or Riemannian optimization costly, delicate, and thus difficult to scale, particularly in large and inhomogeneous systems. We introduce a symplectic optimization framework that addresses this challenge by parameterizing covariance matrices directly as positive-definite symplectic matrices using unit-triangular factorizations. This approach enforces all physical constraints exactly, yielding a globally unconstrained variational formulation of the bosonic ground-state problem. The unconstrained structure also naturally supports solution reuse across nearby Hamiltonians: warm-starting from previously optimized covariance matrices substantially reduces the number of optimization steps required for convergence in families of related configurations, as encountered in crystal lattices, molecular systems, and fluids. We demonstrate the method on weakly dipole-coupled lattices, recovering ground-state energies, covariance matrices, and spectral gaps accurately. The framework further provides a foundation for large-scale approximate treatments of weakly non-quadratic interactions and offers potential scaling advantages through tensor-network enhancements.

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This paper contributes to the Bosonic & Continuous-Variable Quantum Computing research area in the Quantum Articles archive.
It adds a 2026 reference point for readers tracking recent quantum research.
Computing Gaussian ground states via variational optimization is challenging because the covariance matrices must satisfy the uncertainty principle, rendering constrained or...

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References & Citation Signals

[1] DOI https://doi.org/arXiv:2601.20832 [2] arXiv https://arxiv.org/abs/2601.20832 [3] Publisher https://arxiv.org/abs/2601.20832

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