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arxiv: 2406.01635 · v1 · pith:NVUERNRQ · submitted 2024-06-02 · physics.data-an · hep-ex

SwdFold:A Reweighting and Unfolding method based on Optimal Transport Theory

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classification physics.data-an hep-ex
keywords unfoldingdatadistributionshigh-energymethodoptimalphysicsreweighting
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High-energy physics experiments rely heavily on precise measurements of energy and momentum, yet face significant challenges due to detector limitations, calibration errors, and the intrinsic nature of particle interactions. Traditional unfolding techniques have been employed to correct for these distortions, yet they often suffer from model dependency and stability issues. We present a novel method, SwdFold, which utilizes the principles of optimal transport to provide a robust, model-independent framework to estimate the probability density ratio for data unfolding. It not only unfold the toy experimental event by reweighted simulated data distributions closely with true distributions but also maintains the integrity of physical features across various observables. We can expect it can enable more reliable predictions and comprehensive analyses as a high precision reweighting and unfolding tool in high-energy physics.

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Reviewed papers in the Pith corpus that reference this work. Sorted by Pith novelty score.

  1. Reweighting Adversarial Networks for Unbinned Unfolding

    hep-ph 2026-06 unverdicted novelty 7.0

    RANs generalize moment unfolding to full phase-space unbinned unfolding via detector-level Wasserstein critics without requiring support overlap or multiple iterations.