Saved in:
Bibliographic Details
Main Authors: Rao, Heng, Gu, Yu, Zhang, Jason Zipeng, Yu, Ge, Cao, Yang, Chen, Minghan
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2409.12816
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866909412613947392
author Rao, Heng
Gu, Yu
Zhang, Jason Zipeng
Yu, Ge
Cao, Yang
Chen, Minghan
author_facet Rao, Heng
Gu, Yu
Zhang, Jason Zipeng
Yu, Ge
Cao, Yang
Chen, Minghan
contents Biological oscillations are periodic changes in various signaling processes crucial for the proper functioning of living organisms. These oscillations are modeled by ordinary differential equations, with coefficient variations leading to diverse periodic behaviors, typically measured by oscillatory frequencies. This paper explores sampling techniques for neural networks to model the relationship between system coefficients and oscillatory frequency. However, the scarcity of oscillations in the vast coefficient space results in many samples exhibiting non-periodic behaviors, and small coefficient changes near oscillation boundaries can significantly alter oscillatory properties. This leads to non-oscillatory bias and boundary sensitivity, making accurate predictions difficult. While existing importance and uncertainty sampling approaches partially mitigate these challenges, they either fail to resolve the sensitivity problem or result in redundant sampling. To address these limitations, we propose the Hierarchical Gradient-based Genetic Sampling (HGGS) framework, which improves the accuracy of neural network predictions for biological oscillations. The first layer, Gradient-based Filtering, extracts sensitive oscillation boundaries and removes redundant non-oscillatory samples, creating a balanced coarse dataset. The second layer, Multigrid Genetic Sampling, utilizes residual information to refine these boundaries and explore new high-residual regions, increasing data diversity for model training. Experimental results demonstrate that HGGS outperforms seven comparative sampling methods across four biological systems, highlighting its effectiveness in enhancing sampling and prediction accuracy.
format Preprint
id arxiv_https___arxiv_org_abs_2409_12816
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Hierarchical Gradient-Based Genetic Sampling for Accurate Prediction of Biological Oscillations
Rao, Heng
Gu, Yu
Zhang, Jason Zipeng
Yu, Ge
Cao, Yang
Chen, Minghan
Machine Learning
Biological oscillations are periodic changes in various signaling processes crucial for the proper functioning of living organisms. These oscillations are modeled by ordinary differential equations, with coefficient variations leading to diverse periodic behaviors, typically measured by oscillatory frequencies. This paper explores sampling techniques for neural networks to model the relationship between system coefficients and oscillatory frequency. However, the scarcity of oscillations in the vast coefficient space results in many samples exhibiting non-periodic behaviors, and small coefficient changes near oscillation boundaries can significantly alter oscillatory properties. This leads to non-oscillatory bias and boundary sensitivity, making accurate predictions difficult. While existing importance and uncertainty sampling approaches partially mitigate these challenges, they either fail to resolve the sensitivity problem or result in redundant sampling. To address these limitations, we propose the Hierarchical Gradient-based Genetic Sampling (HGGS) framework, which improves the accuracy of neural network predictions for biological oscillations. The first layer, Gradient-based Filtering, extracts sensitive oscillation boundaries and removes redundant non-oscillatory samples, creating a balanced coarse dataset. The second layer, Multigrid Genetic Sampling, utilizes residual information to refine these boundaries and explore new high-residual regions, increasing data diversity for model training. Experimental results demonstrate that HGGS outperforms seven comparative sampling methods across four biological systems, highlighting its effectiveness in enhancing sampling and prediction accuracy.
title Hierarchical Gradient-Based Genetic Sampling for Accurate Prediction of Biological Oscillations
topic Machine Learning
url https://arxiv.org/abs/2409.12816