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Main Authors: Rose, Nathaniel, Chuang, Hannah, Andrade-Rodriguez, Manuel A, Parashar, Rishi, Or, Dani, Maini, Parikshit
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2507.12716
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author Rose, Nathaniel
Chuang, Hannah
Andrade-Rodriguez, Manuel A
Parashar, Rishi
Or, Dani
Maini, Parikshit
author_facet Rose, Nathaniel
Chuang, Hannah
Andrade-Rodriguez, Manuel A
Parashar, Rishi
Or, Dani
Maini, Parikshit
contents Soil moisture is a quantity of interest in many application areas including agriculture and climate modeling. Existing methods are not suitable for scale applications due to large deployment costs in high-resolution sensing applications such as for variable irrigation. In this work, we design, build and field deploy an autonomous mobile robot, MoistureMapper, for soil moisture sensing. The robot is equipped with Time Domain Reflectometry (TDR) sensors and a direct push drill mechanism for deploying the sensor to measure volumetric water content in the soil. Additionally, we implement and evaluate multiple adaptive sampling strategies based on a Gaussian Process based modeling to build a spatial mapping of moisture distribution in the soil. We present results from large scale computational simulations and proof-of-concept deployment on the field. The adaptive sampling approach outperforms a greedy benchmark approach and results in up to 30\% reduction in travel distance and 5\% reduction in variance in the reconstructed moisture maps. Link to video showing field experiments: https://youtu.be/S4bJ4tRzObg
format Preprint
id arxiv_https___arxiv_org_abs_2507_12716
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle MoistureMapper: An Autonomous Mobile Robot for High-Resolution Soil Moisture Mapping at Scale
Rose, Nathaniel
Chuang, Hannah
Andrade-Rodriguez, Manuel A
Parashar, Rishi
Or, Dani
Maini, Parikshit
Robotics
Soil moisture is a quantity of interest in many application areas including agriculture and climate modeling. Existing methods are not suitable for scale applications due to large deployment costs in high-resolution sensing applications such as for variable irrigation. In this work, we design, build and field deploy an autonomous mobile robot, MoistureMapper, for soil moisture sensing. The robot is equipped with Time Domain Reflectometry (TDR) sensors and a direct push drill mechanism for deploying the sensor to measure volumetric water content in the soil. Additionally, we implement and evaluate multiple adaptive sampling strategies based on a Gaussian Process based modeling to build a spatial mapping of moisture distribution in the soil. We present results from large scale computational simulations and proof-of-concept deployment on the field. The adaptive sampling approach outperforms a greedy benchmark approach and results in up to 30\% reduction in travel distance and 5\% reduction in variance in the reconstructed moisture maps. Link to video showing field experiments: https://youtu.be/S4bJ4tRzObg
title MoistureMapper: An Autonomous Mobile Robot for High-Resolution Soil Moisture Mapping at Scale
topic Robotics
url https://arxiv.org/abs/2507.12716