Methods and experiments for analysing hard-bottom layer changes and monitoring wheel sink depth in paddy fields

IF 8.9 1区农林科学 Q1 AGRICULTURE, MULTIDISCIPLINARY

Computers and Electronics in Agriculture Pub Date : 2025-07-24 DOI:10.1016/j.compag.2025.110760

Tuanpeng Tu , Xiwen Luo , Lian Hu , Sun-Ok Chung , Jie He , Runmao Zhao , Pei Wang , Gaolong Chen , Dawen Feng , Mengdong Yue , Zhongxian Man , Md Rejaul Karim , Qingqiang Ruan , Xiongbiao Jiang , Peitian Wu

{"title":"Methods and experiments for analysing hard-bottom layer changes and monitoring wheel sink depth in paddy fields","authors":"Tuanpeng Tu , Xiwen Luo , Lian Hu , Sun-Ok Chung , Jie He , Runmao Zhao , Pei Wang , Gaolong Chen , Dawen Feng , Mengdong Yue , Zhongxian Man , Md Rejaul Karim , Qingqiang Ruan , Xiongbiao Jiang , Peitian Wu","doi":"10.1016/j.compag.2025.110760","DOIUrl":null,"url":null,"abstract":"<div><div>This study aims to enhance smart agricultural machinery for more efficient and high-quality rice production by addressing the challenge of sensing wheel rut depth in paddy fields. Monitoring the hard-bottom layer beneath the tillage zone is difficult due to repeated machinery rolling. An unmanned rice direct seeder, which shares the same mobile chassis as the rice transplanter, was equipped with a dual-antenna Global Navigation Satellite System and dual Attitude and Heading Reference System sensors, and was used as a sensing platform. Methods were developed to calibrate sensors, remove outliers, and estimate implement height using numerical fitting and interquartile range detection. Soil compaction and wheel rut depth measurements were used to compare hard-bottom variations in dry and wet fields. A spatial motion model was created to measure wheel rut depth based on relationships between antenna-to-wheel and antenna-to-implement distances. Digital modeling and interpolation techniques were used to generate accurate models of the mud surface and hard-bottom layer for depth estimation across the field. Field trials showed repetitive rolling in dry fields created localized hard soil layers and increased compaction, while minimal changes occurred in wet fields. The wheel rut depth in dry fields was under 1.0 cm after three passes, but in wet fields, it ranged from 1.9 to 2.9 cm after 2 to 7 passes, with decreasing increments. Wheel sink sensing experiments achieved a standard deviation of 0.678 cm. The surface slope of the paddy field measured by the unmanned direct seeder was 0.03°, which is smaller than the slope of the hard bottom layer at 0.07°. Sink depths were greater in low-lying areas, averaging 23.47 cm, with a variance of 1.84 cm and a maximum depth of 38.10 cm. On a 5-hectare rice farm, the rice transplanter measured mean wheel rut depths of 22.15 cm (variance: 2.17 cm) in Area I and 22.60 cm (variance: 2.53 cm) in Area II. The proposed methods enable continuous, precise monitoring of hard-bottom layer changes and wheel rut depths, characterize the effects of repeated rolling, and produce critical terrain maps. These results support adaptive speed control and entrapment prevention strategies for unmanned smart farm machinery.</div></div>","PeriodicalId":50627,"journal":{"name":"Computers and Electronics in Agriculture","volume":"238 ","pages":"Article 110760"},"PeriodicalIF":8.9000,"publicationDate":"2025-07-24","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Computers and Electronics in Agriculture","FirstCategoryId":"97","ListUrlMain":"https://www.sciencedirect.com/science/article/pii/S016816992500866X","RegionNum":1,"RegionCategory":"农林科学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"AGRICULTURE, MULTIDISCIPLINARY","Score":null,"Total":0}

引用次数: 0

Abstract

This study aims to enhance smart agricultural machinery for more efficient and high-quality rice production by addressing the challenge of sensing wheel rut depth in paddy fields. Monitoring the hard-bottom layer beneath the tillage zone is difficult due to repeated machinery rolling. An unmanned rice direct seeder, which shares the same mobile chassis as the rice transplanter, was equipped with a dual-antenna Global Navigation Satellite System and dual Attitude and Heading Reference System sensors, and was used as a sensing platform. Methods were developed to calibrate sensors, remove outliers, and estimate implement height using numerical fitting and interquartile range detection. Soil compaction and wheel rut depth measurements were used to compare hard-bottom variations in dry and wet fields. A spatial motion model was created to measure wheel rut depth based on relationships between antenna-to-wheel and antenna-to-implement distances. Digital modeling and interpolation techniques were used to generate accurate models of the mud surface and hard-bottom layer for depth estimation across the field. Field trials showed repetitive rolling in dry fields created localized hard soil layers and increased compaction, while minimal changes occurred in wet fields. The wheel rut depth in dry fields was under 1.0 cm after three passes, but in wet fields, it ranged from 1.9 to 2.9 cm after 2 to 7 passes, with decreasing increments. Wheel sink sensing experiments achieved a standard deviation of 0.678 cm. The surface slope of the paddy field measured by the unmanned direct seeder was 0.03°, which is smaller than the slope of the hard bottom layer at 0.07°. Sink depths were greater in low-lying areas, averaging 23.47 cm, with a variance of 1.84 cm and a maximum depth of 38.10 cm. On a 5-hectare rice farm, the rice transplanter measured mean wheel rut depths of 22.15 cm (variance: 2.17 cm) in Area I and 22.60 cm (variance: 2.53 cm) in Area II. The proposed methods enable continuous, precise monitoring of hard-bottom layer changes and wheel rut depths, characterize the effects of repeated rolling, and produce critical terrain maps. These results support adaptive speed control and entrapment prevention strategies for unmanned smart farm machinery.

查看原文本刊更多论文

水田硬底层变化分析及轮毂沉降深度监测方法与试验

本研究旨在通过解决稻田轮辙深度感知的挑战，增强智能农业机械，提高水稻生产效率和质量。由于机械反复碾压，很难监测耕作区下的硬底土层。无人水稻直接播种机与水稻插秧机共用一个移动底盘，配备了双天线全球导航卫星系统和双姿态和航向参考系统传感器，并用作传感平台。开发了使用数值拟合和四分位数距离检测来校准传感器、去除异常值和估计执行高度的方法。土壤压实和车轮车辙深度测量用于比较干田和湿田的硬底变化。基于天线到车轮和天线到机具距离的关系，建立了车轮车辙深度的空间运动模型。采用数字建模和插值技术生成泥浆表面和硬底层的精确模型，用于整个油田的深度估计。田间试验表明，在干旱地区重复滚动会造成局部硬土层，增加压实，而在潮湿地区则变化很小。旱地轮辙深度在3道后小于1.0 cm，湿地轮辙深度在2 ~ 7道后为1.9 ~ 2.9 cm，且轮辙深度逐渐减小。车轮沉降传感实验的标准差为0.678 cm。无人直接播种机测得的水田地表坡度为0.03°，小于硬底层0.07°的坡度。低洼地区的沉降深度较大，平均为23.47 cm，差异为1.84 cm，最大深度为38.10 cm。在一个5公顷的水稻农场上，水稻插秧机在I区测得平均轮辙深度为22.15厘米（方差为2.17厘米），在II区测得平均轮辙深度为22.60厘米（方差为2.53厘米）。所提出的方法能够连续、精确地监测硬底层变化和车轮车辙深度，描述重复滚动的影响，并生成关键的地形图。这些结果为无人智能农业机械的自适应速度控制和陷阱预防策略提供了支持。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Computers and Electronics in Agriculture 工程技术-计算机：跨学科应用

CiteScore

15.30

自引率

14.50%

发文量

800

审稿时长

62 days

期刊介绍： Computers and Electronics in Agriculture provides international coverage of advancements in computer hardware, software, electronic instrumentation, and control systems applied to agricultural challenges. Encompassing agronomy, horticulture, forestry, aquaculture, and animal farming, the journal publishes original papers, reviews, and applications notes. It explores the use of computers and electronics in plant or animal agricultural production, covering topics like agricultural soils, water, pests, controlled environments, and waste. The scope extends to on-farm post-harvest operations and relevant technologies, including artificial intelligence, sensors, machine vision, robotics, networking, and simulation modeling. Its companion journal, Smart Agricultural Technology, continues the focus on smart applications in production agriculture.