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Main Authors: Luo, Shiyuan, Yu, Runlong, Qiu, Chonghao, Ghosh, Rahul, Ladwig, Robert, Hanson, Paul C., Xie, Yiqun, Jia, Xiaowei
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2509.14563
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author Luo, Shiyuan
Yu, Runlong
Qiu, Chonghao
Ghosh, Rahul
Ladwig, Robert
Hanson, Paul C.
Xie, Yiqun
Jia, Xiaowei
author_facet Luo, Shiyuan
Yu, Runlong
Qiu, Chonghao
Ghosh, Rahul
Ladwig, Robert
Hanson, Paul C.
Xie, Yiqun
Jia, Xiaowei
contents The discovery of environmental knowledge depends on labeled task-specific data, but is often constrained by the high cost of data collection. Existing machine learning approaches usually struggle to generalize in data-sparse or atypical conditions. To this end, we propose an Augmentation-Adaptive Self-Supervised Learning (A$^2$SL) framework, which retrieves relevant observational samples to enhance modeling of the target ecosystem. Specifically, we introduce a multi-level pairwise learning loss to train a scenario encoder that captures varying degrees of similarity among scenarios. These learned similarities drive a retrieval mechanism that supplements a target scenario with relevant data from different locations or time periods. Furthermore, to better handle variable scenarios, particularly under atypical or extreme conditions where traditional models struggle, we design an augmentation-adaptive mechanism that selectively enhances these scenarios through targeted data augmentation. Using freshwater ecosystems as a case study, we evaluate A$^2$SL in modeling water temperature and dissolved oxygen dynamics in real-world lakes. Experimental results show that A$^2$SL significantly improves predictive accuracy and enhances robustness in data-scarce and atypical scenarios. Although this study focuses on freshwater ecosystems, the A$^2$SL framework offers a broadly applicable solution in various scientific domains.
format Preprint
id arxiv_https___arxiv_org_abs_2509_14563
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Learning to Retrieve for Environmental Knowledge Discovery: An Augmentation-Adaptive Self-Supervised Learning Framework
Luo, Shiyuan
Yu, Runlong
Qiu, Chonghao
Ghosh, Rahul
Ladwig, Robert
Hanson, Paul C.
Xie, Yiqun
Jia, Xiaowei
Machine Learning
The discovery of environmental knowledge depends on labeled task-specific data, but is often constrained by the high cost of data collection. Existing machine learning approaches usually struggle to generalize in data-sparse or atypical conditions. To this end, we propose an Augmentation-Adaptive Self-Supervised Learning (A$^2$SL) framework, which retrieves relevant observational samples to enhance modeling of the target ecosystem. Specifically, we introduce a multi-level pairwise learning loss to train a scenario encoder that captures varying degrees of similarity among scenarios. These learned similarities drive a retrieval mechanism that supplements a target scenario with relevant data from different locations or time periods. Furthermore, to better handle variable scenarios, particularly under atypical or extreme conditions where traditional models struggle, we design an augmentation-adaptive mechanism that selectively enhances these scenarios through targeted data augmentation. Using freshwater ecosystems as a case study, we evaluate A$^2$SL in modeling water temperature and dissolved oxygen dynamics in real-world lakes. Experimental results show that A$^2$SL significantly improves predictive accuracy and enhances robustness in data-scarce and atypical scenarios. Although this study focuses on freshwater ecosystems, the A$^2$SL framework offers a broadly applicable solution in various scientific domains.
title Learning to Retrieve for Environmental Knowledge Discovery: An Augmentation-Adaptive Self-Supervised Learning Framework
topic Machine Learning
url https://arxiv.org/abs/2509.14563