Exploiting Symmetry in Quantum Reservoir Computing
Abstract
Symmetry is a powerful inductive bias, but in quantum reservoir computing (QRC) it cannot be imposed only by making the reservoir symmetric. QRC maps inputs through fixed quantum dynamics into nonlinear expectation-value features and trains only a classical readout, so the relevant symmetry must be visible in the measured feature map. We study cyclic forecasting tasks, such as sensors around a turbine or weather stations along a latitude circle, where the same local pattern should be forecast by...
Description / Details
Symmetry is a powerful inductive bias, but in quantum reservoir computing (QRC) it cannot be imposed only by making the reservoir symmetric. QRC maps inputs through fixed quantum dynamics into nonlinear expectation-value features and trains only a classical readout, so the relevant symmetry must be visible in the measured feature map. We study cyclic forecasting tasks, such as sensors around a turbine or weather stations along a latitude circle, where the same local pattern should be forecast by the same rule wherever it appears on the ring. Thus, rotating the input by one site should rotate, not change, the predicted field. We show that a symmetric Hamiltonian is not enough: even large Pauli measurement sets can fail if their channels do not match the data symmetry, since optimization cannot recover channels that were never measured. We address this through observable-orbit completion, which measures symmetry-related observable channels and aligns encoding, dynamics, measurement, and readout. The strongest gains arise from aligning all four interfaces together, with matched spin-ring, real-weather, and IBM hardware checks supporting the same measured-span mechanism.
Source: arXiv:2607.01187v1 - http://arxiv.org/abs/2607.01187v1 PDF: https://arxiv.org/pdf/2607.01187v1 Original Link: http://arxiv.org/abs/2607.01187v1
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Jul 2, 2026
Quantum Computing
Quantum Physics
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