Multi-Sensor Integration and Machine Learning for High-Resolution Classification of Herbivore Foraging Behavior
The study used Random Test-Split (RTS) and Cross-Validation (CV) machine learning methods to test different models to classify cattle behavior foraging behaviors states, foraging activities, posture, and activity by posture, using GPS coupled accelerometer data with 12-hour / days continuous recording observation as supporting ground truth. RTS in XGBoost performing best for general activity state classification, while CV in Random Forest excelled in more detailed foraging activities and activity-posture classifications. Key movement indicators like speed, Actindex and sensor values (x, y, and z) were vital in predicting behaviors, suggesting specific sensors for tracking behaviors of interest to ranchers. The results highlight the benefits of continuous monitoring and advanced data analysis for real-time livestock tracking, leading to better grazing management, improved animal welfare, and more sustainable land use.
Funding
Using Smart Foodscapes to Enhance the Sustainability of Western Rangelands
National Institute of Food and Agriculture
Find out more...History
Data contact name
Muzzo, IddyData contact email
iddy.muzzo@usu.eduPublisher
Ag Data CommonsIntended use
The intended use of this information is to advance the understanding and application of machine learning techniques in livestock behavior monitoring. Specifically, the study's findings are aimed at: -Improving Livestock Management: By providing accurate classification of cattle behaviors, ranchers can make informed decisions about grazing management, improving animal welfare and optimizing land use. -Promoting Sustainable Agriculture: The ability to monitor and predict cattle behavior in real-time supports sustainable grazing practices by reducing overgrazing and enhancing pasture management. -Enhancing Technological Adoption in Agriculture: The study demonstrates the practical utility of GPS and accelerometer data, coupled with machine learning models like XGBoost and Random Forest, encouraging the adoption of advanced technologies for livestock tracking. -Supporting Research and Development: The results contribute to the broader field of precision agriculture, offering a foundation for further research into sensor-based livestock monitoring systems. -Providing Practical Tools for Ranchers: By identifying key movement indicators (e.g., speed, Actindex, sensor values), the study suggests specific sensors and methodologies that ranchers can use to track behaviors of interest effectively. In summary, this information is intended to bridge the gap between advanced data analysis techniques and practical applications in livestock management, fostering innovation and sustainability in agriculture.Temporal Extent Start Date
2021-09-21Temporal Extent End Date
2026-08-31Frequency
- asNeeded
Theme
- Geospatial
Geographic Coverage
{"type":"FeatureCollection","features":[{"geometry":{"type":"Point","coordinates":[-111.8368798,41.6939214]},"type":"Feature","properties":{}}]}Geographic location - description
USU Richmond Research farm (41.9227° N, 111.8136° W) Richmond, Utah, United States of AmericaISO Topic Category
- environment
- farming
- geoscientificInformation
- location
National Agricultural Library Thesaurus terms
artificial intelligence; models; cattle; foraging; global positioning systems; accelerometers; ranchers; monitoring; grazing management; animal welfare; sustainable land management; herbivores; livestock husbandry; land use; sustainable agriculture; overgrazing; pasture management; precision agricultureOMB Bureau Code
- 005:20 - National Institute of Food and Agriculture
OMB Program Code
- 005:037 - Research and Education
Pending citation
- Yes
Public Access Level
- Public
