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利用模式挖掘通过加速度计远程早期检测牛流行热在牛群中的潜力。

Potential of accelerometers to remotely early detect bovine ephemeral fever in cattle using pattern mining.

作者信息

Trieu Ly Ly, Bailey Derek W, Cao Huiping, Son Tran Cao, Macor Justin, Trotter Mark G, O'Connor Lauren, Tobin Colin T

机构信息

Department of Computer Science, New Mexico State University, Las Cruces, NM 88003, USA.

Department of Animal and Ranges Sciences, New Mexico State University, Las Cruces, NM 88003, USA.

出版信息

Transl Anim Sci. 2025 Jan 25;9:txaf008. doi: 10.1093/tas/txaf008. eCollection 2025.

DOI:10.1093/tas/txaf008
PMID:39917049
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11799742/
Abstract

Bovine Ephemeral Fever (BEF), caused by an arthropod-borne rhabdovirus, is widespread in tropical and subtropical regions. It affects cattle with symptoms of fever, lameness, inappetence and in some situations can result in mortality. The goal of this study is to determine if accelerometer data can be used to identify the behavior patterns that occur when cattle become ill from BEF. Eight heifers in a separate experiment were monitored with 3-axis accelerometers sensors. Movement variation (MV) was calculated from accelerometer data (25 Hz) using 1-min epochs and then averaged hourly. Two different approaches, cosine similarity (CS) and deviation from previous behavioral patterns, were developed to autonomously detect patterns and recognize the onset of sickness in cattle using accelerometer data. Analyses show that one heifer had behavioral changes one day before the manager observed BEF, and another heifer had behavioral changes on the same day the manager observed BEF. The other six heifers did not display any BEF symptoms. To validate the efficacy of our analytical approaches, we employed them on a separate commercial herd of 73 cows where 4 of the 27 monitored cows were observed with BEF symptoms. Predictions were either on the day or even the day prior to the manager's observation and diagnosis. There were likely no false positives in the first or second trials using the deviation algorithm with formula, but there were several false positives with the other algorithms. These case studies demonstrate the potential of accelerometer data to autonomously detect disease onset, in some cases before it was apparent to the human observer. However, more research is needed to minimize false positives that may occur from other similar diseases, abnormal weather events or cyclical changes in behavior such as estrus is required.

摘要

牛流行热(BEF)由一种节肢动物传播的弹状病毒引起,在热带和亚热带地区广泛传播。它会影响牛群,导致发热、跛行、食欲不振等症状,在某些情况下还会导致死亡。本研究的目的是确定加速度计数据是否可用于识别牛感染牛流行热生病时出现的行为模式。在一项单独的实验中,用三轴加速度计传感器对八头小母牛进行了监测。使用1分钟的时间间隔,根据加速度计数据(25赫兹)计算运动变化(MV),然后每小时求平均值。开发了两种不同的方法,即余弦相似度(CS)和与先前行为模式的偏差,以利用加速度计数据自动检测牛的行为模式并识别疾病发作。分析表明,一头小母牛在管理人员观察到牛流行热的前一天出现了行为变化,另一头小母牛在管理人员观察到牛流行热的当天出现了行为变化。其他六头小母牛未表现出任何牛流行热症状。为了验证我们分析方法的有效性,我们在另一群73头奶牛的商业牛群中应用了这些方法,其中27头被监测的奶牛中有4头出现了牛流行热症状。预测结果要么是在管理人员观察和诊断的当天,甚至是前一天。使用带有公式的偏差算法在第一次或第二次试验中可能没有误报,但其他算法有几个误报。这些案例研究表明,加速度计数据有可能自动检测疾病发作,在某些情况下,甚至在人类观察者明显察觉之前。然而,需要更多的研究来尽量减少可能由其他类似疾病、异常天气事件或行为的周期性变化(如发情期)引起的误报。

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