Saved in:
Bibliographic Details
Main Authors: Cohen, Abigail R., Sun, Yuming, Qin, Zhihao, Muriki, Harsh S., Xiao, Zihao, Lee, Yeonju, Housley, Matthew, Sharkey, Andrew F., Ferrarezi, Rhuanito S., Li, Jing, Gan, Lu, Chen, Yongsheng
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2509.12247
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866917106012913664
author Cohen, Abigail R.
Sun, Yuming
Qin, Zhihao
Muriki, Harsh S.
Xiao, Zihao
Lee, Yeonju
Housley, Matthew
Sharkey, Andrew F.
Ferrarezi, Rhuanito S.
Li, Jing
Gan, Lu
Chen, Yongsheng
author_facet Cohen, Abigail R.
Sun, Yuming
Qin, Zhihao
Muriki, Harsh S.
Xiao, Zihao
Lee, Yeonju
Housley, Matthew
Sharkey, Andrew F.
Ferrarezi, Rhuanito S.
Li, Jing
Gan, Lu
Chen, Yongsheng
contents Efficient nutrient management is critical for crop growth and sustainable resource consumption (e.g., nitrogen, energy). Current approaches require lengthy analyses, preventing real-time optimization; similarly, imaging facilitates rapid phenotyping but can be computationally intensive, preventing deployment under resource constraints. This study proposes a flexible, tiered pipeline for anomaly detection and status estimation (fresh weight, dry mass, and tissue nutrients), including a comprehensive energy analysis of approaches that span the efficiency-accuracy spectrum. Using a nutrient depletion experiment with three treatments (T1-100%, T2-50%, and T3-25% fertilizer strength) and multispectral imaging (MSI), we developed a hierarchical pipeline using an autoencoder (AE) for early warning. Further, we compared two status estimation modules of different complexity for more detailed analysis: vegetation index (VI) features with machine learning (Random Forest, RF) and raw whole-image deep learning (Vision Transformer, ViT). Results demonstrated high-efficiency anomaly detection (73% net detection of T3 samples 9 days after transplanting) at substantially lower energy than embodied energy in wasted nitrogen. The state estimation modules show trade-offs, with ViT outperforming RF on phosphorus and calcium estimation (R2 0.61 vs. 0.58, 0.48 vs. 0.35) at higher energy cost. With our modular pipeline, this work opens opportunities for edge diagnostics and practical opportunities for agricultural sustainability.
format Preprint
id arxiv_https___arxiv_org_abs_2509_12247
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Modular, On-Site Solutions with Lightweight Anomaly Detection for Sustainable Nutrient Management in Agriculture
Cohen, Abigail R.
Sun, Yuming
Qin, Zhihao
Muriki, Harsh S.
Xiao, Zihao
Lee, Yeonju
Housley, Matthew
Sharkey, Andrew F.
Ferrarezi, Rhuanito S.
Li, Jing
Gan, Lu
Chen, Yongsheng
Computer Vision and Pattern Recognition
Artificial Intelligence
Efficient nutrient management is critical for crop growth and sustainable resource consumption (e.g., nitrogen, energy). Current approaches require lengthy analyses, preventing real-time optimization; similarly, imaging facilitates rapid phenotyping but can be computationally intensive, preventing deployment under resource constraints. This study proposes a flexible, tiered pipeline for anomaly detection and status estimation (fresh weight, dry mass, and tissue nutrients), including a comprehensive energy analysis of approaches that span the efficiency-accuracy spectrum. Using a nutrient depletion experiment with three treatments (T1-100%, T2-50%, and T3-25% fertilizer strength) and multispectral imaging (MSI), we developed a hierarchical pipeline using an autoencoder (AE) for early warning. Further, we compared two status estimation modules of different complexity for more detailed analysis: vegetation index (VI) features with machine learning (Random Forest, RF) and raw whole-image deep learning (Vision Transformer, ViT). Results demonstrated high-efficiency anomaly detection (73% net detection of T3 samples 9 days after transplanting) at substantially lower energy than embodied energy in wasted nitrogen. The state estimation modules show trade-offs, with ViT outperforming RF on phosphorus and calcium estimation (R2 0.61 vs. 0.58, 0.48 vs. 0.35) at higher energy cost. With our modular pipeline, this work opens opportunities for edge diagnostics and practical opportunities for agricultural sustainability.
title Modular, On-Site Solutions with Lightweight Anomaly Detection for Sustainable Nutrient Management in Agriculture
topic Computer Vision and Pattern Recognition
Artificial Intelligence
url https://arxiv.org/abs/2509.12247