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Main Authors: Liu, Chen-Yu, Placidi, Leonardo, Chen, Kuan-Cheng, Chen, Samuel Yen-Chi, Matos, Gabriel
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2509.20090
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author Liu, Chen-Yu
Placidi, Leonardo
Chen, Kuan-Cheng
Chen, Samuel Yen-Chi
Matos, Gabriel
author_facet Liu, Chen-Yu
Placidi, Leonardo
Chen, Kuan-Cheng
Chen, Samuel Yen-Chi
Matos, Gabriel
contents Quantum machine learning (QML) models conventionally rely on repeated measurements (shots) of observables to obtain reliable predictions. This dependence on large shot budgets leads to high inference cost and time overhead, which is particularly problematic as quantum hardware access is typically priced proportionally to the number of shots. In this work we propose You Only Measure Once (Yomo), a simple yet effective design that achieves accurate inference with dramatically fewer measurements, down to the single-shot regime. Yomo replaces Pauli expectation-value outputs with a probability aggregation mechanism and introduces loss functions that encourage sharp predictions. Our theoretical analysis shows that Yomo avoids the shot-scaling limitations inherent to expectation-based models, and our experiments on MNIST and CIFAR-10 confirm that Yomo consistently outperforms baselines across different shot budgets and under simulations with depolarizing channels. By enabling accurate single-shot inference, Yomo substantially reduces the financial and computational costs of deploying QML, thereby lowering the barrier to practical adoption of QML.
format Preprint
id arxiv_https___arxiv_org_abs_2509_20090
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle You Only Measure Once: On Designing Single-Shot Quantum Machine Learning Models
Liu, Chen-Yu
Placidi, Leonardo
Chen, Kuan-Cheng
Chen, Samuel Yen-Chi
Matos, Gabriel
Machine Learning
Quantum Physics
Quantum machine learning (QML) models conventionally rely on repeated measurements (shots) of observables to obtain reliable predictions. This dependence on large shot budgets leads to high inference cost and time overhead, which is particularly problematic as quantum hardware access is typically priced proportionally to the number of shots. In this work we propose You Only Measure Once (Yomo), a simple yet effective design that achieves accurate inference with dramatically fewer measurements, down to the single-shot regime. Yomo replaces Pauli expectation-value outputs with a probability aggregation mechanism and introduces loss functions that encourage sharp predictions. Our theoretical analysis shows that Yomo avoids the shot-scaling limitations inherent to expectation-based models, and our experiments on MNIST and CIFAR-10 confirm that Yomo consistently outperforms baselines across different shot budgets and under simulations with depolarizing channels. By enabling accurate single-shot inference, Yomo substantially reduces the financial and computational costs of deploying QML, thereby lowering the barrier to practical adoption of QML.
title You Only Measure Once: On Designing Single-Shot Quantum Machine Learning Models
topic Machine Learning
Quantum Physics
url https://arxiv.org/abs/2509.20090