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基于机器学习的不同草层高度牧场上放牧绵羊行为分类与分析

Behavior Classification and Analysis of Grazing Sheep on Pasture with Different Sward Surface Heights Using Machine Learning.

作者信息

Jin Zhongming, Guo Leifeng, Shu Hang, Qi Jingwei, Li Yongfeng, Xu Beibei, Zhang Wenju, Wang Kaiwen, Wang Wensheng

机构信息

Agricultural Information Institute, Chinese Academy of Agriculture Sciences, Beijing 100086, China.

AgroBioChem/TERRA, Precision Livestock and Nutrition Unit, Gembloux Agro-Bio Tech, University of Liège, 5030 Gembloux, Belgium.

出版信息

Animals (Basel). 2022 Jul 7;12(14):1744. doi: 10.3390/ani12141744.

DOI:10.3390/ani12141744
PMID:35883291
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9311692/
Abstract

Behavior classification and recognition of sheep are useful for monitoring their health and productivity. The automatic behavior classification of sheep by using wearable devices based on IMU sensors is becoming more prevalent, but there is little consensus on data processing and classification methods. Most classification accuracy tests are conducted on extracted behavior segments, with only a few trained models applied to continuous behavior segments classification. The aim of this study was to evaluate the performance of multiple combinations of algorithms (extreme learning machine (ELM), AdaBoost, stacking), time windows (3, 5 and 11 s) and sensor data (three-axis accelerometer (T-acc), three-axis gyroscope (T-gyr), and T-acc and T-gyr) for grazing sheep behavior classification on continuous behavior segments. The optimal combination was a stacking model at the 3 s time window using T-acc and T-gyr data, which had an accuracy of 87.8% and a Kappa value of 0.836. It was applied to the behavior classification of three grazing sheep continuously for a total of 67.5 h on pasture with three different sward surface heights (SSH). The results revealed that the three sheep had the longest walking, grazing and resting times on the short, medium and tall SHH, respectively. These findings can be used to support grazing sheep management and the evaluation of production performance.

摘要

绵羊行为的分类与识别对于监测其健康状况和生产性能很有用。利用基于惯性测量单元(IMU)传感器的可穿戴设备对绵羊行为进行自动分类正变得越来越普遍,但在数据处理和分类方法上几乎没有达成共识。大多数分类准确性测试是在提取的行为片段上进行的,只有少数训练模型应用于连续行为片段的分类。本研究的目的是评估算法(极限学习机(ELM)、AdaBoost、堆叠)、时间窗口(3、5和11秒)和传感器数据(三轴加速度计(T-acc)、三轴陀螺仪(T-gyr)以及T-acc和T-gyr)的多种组合对连续行为片段上放牧绵羊行为分类的性能。最优组合是在3秒时间窗口使用T-acc和T-gyr数据的堆叠模型,其准确率为87.8%,卡帕值为0.836。该模型应用于三只放牧绵羊在三种不同草层高度(SSH)的牧场上连续67.5小时的行为分类。结果表明,这三只绵羊分别在短、中、高草层高度的草地上行走、放牧和休息的时间最长。这些发现可用于支持放牧绵羊的管理和生产性能评估。

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