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Main Authors: Zhou, Yingtong, Zhou, Yiang, Qu, Zhengxian, Liu, Kang, Tan, Ting
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2601.16792
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author Zhou, Yingtong
Zhou, Yiang
Qu, Zhengxian
Liu, Kang
Tan, Ting
author_facet Zhou, Yingtong
Zhou, Yiang
Qu, Zhengxian
Liu, Kang
Tan, Ting
contents Research on fetal phonocardiogram (fPCG) is challenged by the limited number of abdominal recordings, substantial maternal interference, and marked transmissioninduced signal attenuation that complicate reproducible benchmarking. We present a reproducible dynamic parametric simulator that generates long abdominal fPCG sequences by combining cycle-level fetal S1/S2 event synthesis with a convolutional transmission module and configurable interference and background noise. Model parameters are calibrated cyclewise from real abdominal recordings to capture beat-to-beat variability and to define data-driven admissible ranges for controllable synthesis. The generated signals are validated against real recordings in terms of envelope-based temporal structure and frequency-domain characteristics. The simulator is released as open software to support rapid, reproducible evaluation of fPCG processing methods under controlled acquisition conditions.
format Preprint
id arxiv_https___arxiv_org_abs_2601_16792
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle A Dynamic Parametric Simulator for Fetal Heart Sounds
Zhou, Yingtong
Zhou, Yiang
Qu, Zhengxian
Liu, Kang
Tan, Ting
Signal Processing
Research on fetal phonocardiogram (fPCG) is challenged by the limited number of abdominal recordings, substantial maternal interference, and marked transmissioninduced signal attenuation that complicate reproducible benchmarking. We present a reproducible dynamic parametric simulator that generates long abdominal fPCG sequences by combining cycle-level fetal S1/S2 event synthesis with a convolutional transmission module and configurable interference and background noise. Model parameters are calibrated cyclewise from real abdominal recordings to capture beat-to-beat variability and to define data-driven admissible ranges for controllable synthesis. The generated signals are validated against real recordings in terms of envelope-based temporal structure and frequency-domain characteristics. The simulator is released as open software to support rapid, reproducible evaluation of fPCG processing methods under controlled acquisition conditions.
title A Dynamic Parametric Simulator for Fetal Heart Sounds
topic Signal Processing
url https://arxiv.org/abs/2601.16792