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Auteurs principaux: Zhang, Ci, Li, Huayu, Yang, Changdi, Xia, Jiangnan, Wang, Yanzhi, Ma, Xiaolong, Lu, Jin, Li, Ao, Yuan, Geng
Format: Preprint
Publié: 2025
Sujets:
Accès en ligne:https://arxiv.org/abs/2512.07873
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author Zhang, Ci
Li, Huayu
Yang, Changdi
Xia, Jiangnan
Wang, Yanzhi
Ma, Xiaolong
Lu, Jin
Li, Ao
Yuan, Geng
author_facet Zhang, Ci
Li, Huayu
Yang, Changdi
Xia, Jiangnan
Wang, Yanzhi
Ma, Xiaolong
Lu, Jin
Li, Ao
Yuan, Geng
contents Recent studies show that using diffusion models for time series signal reconstruction holds great promise. However, such approaches remain largely unexplored in the domain of medical time series. The unique characteristics of the physiological time series signals, such as multivariate, high temporal variability, highly noisy, and artifact-prone, make deep learning-based approaches still challenging for tasks such as imputation. Hence, we propose a novel Mixture of Experts (MoE)-based noise estimator within a score-based diffusion framework. Specifically, the Receptive Field Adaptive MoE (RFAMoE) module is designed to enable each channel to adaptively select desired receptive fields throughout the diffusion process. Moreover, recent literature has found that when generating a physiological signal, performing multiple inferences and averaging the reconstructed signals can effectively reduce reconstruction errors, but at the cost of significant computational and latency overhead. We design a Fusion MoE module and innovatively leverage the nature of MoE module to generate K noise signals in parallel, fuse them using a routing mechanism, and complete signal reconstruction in a single inference step. This design not only improves performance over previous methods but also eliminates the substantial computational cost and latency associated with multiple inference processes. Extensive results demonstrate that our proposed framework consistently outperforms diffusion-based SOTA works on different tasks and datasets.
format Preprint
id arxiv_https___arxiv_org_abs_2512_07873
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Advancing time series completion via RFAMoE and MDFF
Zhang, Ci
Li, Huayu
Yang, Changdi
Xia, Jiangnan
Wang, Yanzhi
Ma, Xiaolong
Lu, Jin
Li, Ao
Yuan, Geng
Machine Learning
Artificial Intelligence
Recent studies show that using diffusion models for time series signal reconstruction holds great promise. However, such approaches remain largely unexplored in the domain of medical time series. The unique characteristics of the physiological time series signals, such as multivariate, high temporal variability, highly noisy, and artifact-prone, make deep learning-based approaches still challenging for tasks such as imputation. Hence, we propose a novel Mixture of Experts (MoE)-based noise estimator within a score-based diffusion framework. Specifically, the Receptive Field Adaptive MoE (RFAMoE) module is designed to enable each channel to adaptively select desired receptive fields throughout the diffusion process. Moreover, recent literature has found that when generating a physiological signal, performing multiple inferences and averaging the reconstructed signals can effectively reduce reconstruction errors, but at the cost of significant computational and latency overhead. We design a Fusion MoE module and innovatively leverage the nature of MoE module to generate K noise signals in parallel, fuse them using a routing mechanism, and complete signal reconstruction in a single inference step. This design not only improves performance over previous methods but also eliminates the substantial computational cost and latency associated with multiple inference processes. Extensive results demonstrate that our proposed framework consistently outperforms diffusion-based SOTA works on different tasks and datasets.
title Advancing time series completion via RFAMoE and MDFF
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2512.07873