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Main Authors: Baumann, Markus, Zorn, Maximilian, Gabor, Thomas, Linnhoff-Popien, Claudia, Stein, Jonas
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.28160
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author Baumann, Markus
Zorn, Maximilian
Gabor, Thomas
Linnhoff-Popien, Claudia
Stein, Jonas
author_facet Baumann, Markus
Zorn, Maximilian
Gabor, Thomas
Linnhoff-Popien, Claudia
Stein, Jonas
contents Near-term quantum computers are accessed through repeated circuit executions, which produce finite measurement records rather than exact deterministic outputs. In quantum reservoir computing, these records are converted to feature vectors for a classical readout. The standard expectation-value approach averages all shots from one labeled time step into a single feature vector. This reduces finite-shot noise, but it also gives the readout only one training example from many circuit executions. We introduce split-ensemble training: the same shots are split into groups, and each group average is used as a separate, partially denoised feature vector for the same target. The quantum circuit, task, and measurement budget remain unchanged. Across simulated forecasting benchmarks and real hardware experiments, this simple reorganization improves prediction when full averaging leaves the readout with too few training examples, with the strongest gains observed on hardware. Our results establish shot-record organization as a simple, broadly applicable algorithmic lever for improving near-term quantum learning without additional quantum hardware cost.
format Preprint
id arxiv_https___arxiv_org_abs_2604_28160
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Reorganizing Quantum Measurement Records Improves Time-Series Prediction
Baumann, Markus
Zorn, Maximilian
Gabor, Thomas
Linnhoff-Popien, Claudia
Stein, Jonas
Quantum Physics
Near-term quantum computers are accessed through repeated circuit executions, which produce finite measurement records rather than exact deterministic outputs. In quantum reservoir computing, these records are converted to feature vectors for a classical readout. The standard expectation-value approach averages all shots from one labeled time step into a single feature vector. This reduces finite-shot noise, but it also gives the readout only one training example from many circuit executions. We introduce split-ensemble training: the same shots are split into groups, and each group average is used as a separate, partially denoised feature vector for the same target. The quantum circuit, task, and measurement budget remain unchanged. Across simulated forecasting benchmarks and real hardware experiments, this simple reorganization improves prediction when full averaging leaves the readout with too few training examples, with the strongest gains observed on hardware. Our results establish shot-record organization as a simple, broadly applicable algorithmic lever for improving near-term quantum learning without additional quantum hardware cost.
title Reorganizing Quantum Measurement Records Improves Time-Series Prediction
topic Quantum Physics
url https://arxiv.org/abs/2604.28160