Abstract
Abstract In precision livestock farming, technology-based solutions are used to monitor and manage livestock and support decisions based on on-farm available data. In this study, we developed a methodology to monitor the lying behavior of dairy cows using noisy spatial positioning data, thereby combining time-series segmentation based on statistical changepoints and a machine-learning classification algorithm using bagged decision trees. Position data ( x , y , z -coordinates) collected with an ultra-wide band positioning system from 30 dairy cows housed in a freestall barn were used. After the data preprocessing and selection, statistical changepoints were detected per cow-day (no. included = 331) in normalized 'distance from the center' and ( z ) time series. Accelerometer-based lying bout data were used as a practical ground truth. For the segmentation, changepoint detection was compared with getting-up or lying-down events as indicated by the accelerometers. For the classification of segments into lying or non-lying behavior, two data splitting techniques resulting in 2 different training and test sets were implemented to train and evaluate performance: one based on the data collection day and one based on cow identity. In 85.5% of the lying-down or getting-up events a changepoint was detected in a window of 5 minutes. Of the events where no detection had taken place, 86.2% could be associated with either missing data (large gaps) or a very short lying or non-lying bout. Overall classification and lying behavior prediction performance was above 91% in both independent test sets, with a very high consistency across cow-days. This resulted in sufficient accuracy for automated quantification of lying behavior in dairy cows, for example for health or welfare monitoring purposes.
Highlights
Precision livestock farming solutions typically aim at supporting monitoring and decision taking by farmers using on-farm sensors measuring animal behavior, performance and production support are often noisy time series, prone to errors and variation caused by sensor failure or the harsh and changing farm environments in which they operate, and by the animals' specic physiology itself
The within-bout level and standard deviation of the series, and the standard deviation of the CD across lying and non-lying bouts are given in chosen time series dier across lying and non-lying behavior, which is the basis table 2
A methodology was developed to distinguish lying from non-lying behavior of dairy cows based on spatial uwb (
Summary
Precision livestock farming solutions typically aim at supporting monitoring and decision taking by farmers using on-farm sensors measuring animal behav- [1]. Ior, performance and production support are often noisy time series, prone to errors and variation caused by sensor failure or the harsh and changing farm environments in which they operate, and by the animals' specic physiology itself. The resulting complexity and magnitude of the raw data render them hard to interpret as such by farmers or other end-users. These data have little value without proper (pre-)processing algorithms that translate the raw measures in information informative for the targeted end-users. Because of the physiological stress these animals endure during lactation, timely and specic interventions obviate animal suering and nancial losses
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