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Main Authors: Sun, Yiming, Cheng, Qi, Liu, Licheng, Yu, Runlong, Xie, Yiqun, Jia, Xiaowei
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.07305
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author Sun, Yiming
Cheng, Qi
Liu, Licheng
Yu, Runlong
Xie, Yiqun
Jia, Xiaowei
author_facet Sun, Yiming
Cheng, Qi
Liu, Licheng
Yu, Runlong
Xie, Yiqun
Jia, Xiaowei
contents This paper proposes a new method for crop yield prediction, which is essential for developing management strategies, informing insurance assessments, and ensuring long-term food security. Although existing data-driven approaches have shown promise in this domain, their performance often degrades when applied across large geographic regions and long time periods. This limitation arises from two key challenges: (1) difficulty in jointly capturing short-term and long-term temporal patterns, and (2) inability to effectively accommodate spatial data variability in agricultural systems. Ignoring these issues often leads to unreliable predictions for specific regions or years, which ultimately affects policy decisions and resource allocation. In this paper, we propose a new predictive framework to address these challenges. First, we introduce a new backbone model architecture that captures both short-term daily-scale crop growth dynamics and long-term dependencies across years. To further improve generalization across diverse spatial regions, we augment this model with a retrieval-based adaptation strategy. Recognizing the substantial yield variation across years, we design a novel retrieval-and-refinement pipeline that adjusts retrieved samples by removing cross-year bias not explained by input features. Our experiments on real-world county-level corn yield data over 630 counties in the US demonstrate that our method consistently outperforms different types of baselines. The results also verify the effectiveness of the retrieval-based augmentation method in improving model robustness under spatial heterogeneity.
format Preprint
id arxiv_https___arxiv_org_abs_2603_07305
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Retrieval-Augmented Multi-scale Framework for County-Level Crop Yield Prediction Across Large Regions
Sun, Yiming
Cheng, Qi
Liu, Licheng
Yu, Runlong
Xie, Yiqun
Jia, Xiaowei
Machine Learning
This paper proposes a new method for crop yield prediction, which is essential for developing management strategies, informing insurance assessments, and ensuring long-term food security. Although existing data-driven approaches have shown promise in this domain, their performance often degrades when applied across large geographic regions and long time periods. This limitation arises from two key challenges: (1) difficulty in jointly capturing short-term and long-term temporal patterns, and (2) inability to effectively accommodate spatial data variability in agricultural systems. Ignoring these issues often leads to unreliable predictions for specific regions or years, which ultimately affects policy decisions and resource allocation. In this paper, we propose a new predictive framework to address these challenges. First, we introduce a new backbone model architecture that captures both short-term daily-scale crop growth dynamics and long-term dependencies across years. To further improve generalization across diverse spatial regions, we augment this model with a retrieval-based adaptation strategy. Recognizing the substantial yield variation across years, we design a novel retrieval-and-refinement pipeline that adjusts retrieved samples by removing cross-year bias not explained by input features. Our experiments on real-world county-level corn yield data over 630 counties in the US demonstrate that our method consistently outperforms different types of baselines. The results also verify the effectiveness of the retrieval-based augmentation method in improving model robustness under spatial heterogeneity.
title Retrieval-Augmented Multi-scale Framework for County-Level Crop Yield Prediction Across Large Regions
topic Machine Learning
url https://arxiv.org/abs/2603.07305