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Deep learning and image processing for high-throughput udder phenotyping in dairy cows.

Maria E Montes1, Guilherme L Menezes1, Douglas J Reinemann2

  • 1Department of Animal and Dairy Sciences, University of Wisconsin-Madison, Madison, WI 53706.

Journal of Dairy Science
|April 5, 2026
PubMed
Summary

This study developed an automated pipeline for udder phenotyping in dairy cows using depth images. Larger udder area correlated with higher milk yields, aiding breeding and management.

Keywords:
artificial intelligencerobotic milkingudder morphometrics

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Area of Science:

  • Animal Science
  • Computer Vision
  • Agricultural Engineering

Background:

  • Udder conformation is vital for dairy cow health and productivity, especially in Automated Milking Systems (AMS).
  • Accurate phenotyping is essential for genetic selection, health monitoring, and welfare assessments.
  • Existing methods for udder phenotyping can be labor-intensive and subjective.

Purpose of the Study:

  • To develop an automated pipeline for extracting udder phenotypes from depth images.
  • To evaluate the association between udder conformation traits and milk production performance.
  • To enable high-throughput phenotyping for improved dairy cattle management.

Main Methods:

  • Depth videos of 150 Holstein cows were recorded in an AMS environment.
  • Convolutional Neural Networks (CNNs) were trained for image segmentation and keypoint detection.
  • The pipeline integrated CNNs with image processing for udder segmentation, teat localization, and phenotype extraction.

Main Results:

  • The automated pipeline achieved high accuracy in udder segmentation (IoU = 0.93) and teat localization (NED = 0.061).
  • Extracted phenotypes included udder/quarter circularity, eccentricity, surface area, volume, and teat dimensions.
  • Larger udder area was significantly associated with higher milk yields (r = 0.55).
  • Increased parity correlated with larger udder perimeter, longer teats, and greater teat distance.

Conclusions:

  • The developed pipeline offers a robust and efficient solution for high-throughput udder phenotyping.
  • Udder conformation traits are valuable indicators of milk production and can inform breeding strategies.
  • This technology has significant implications for dairy cattle breeding, health management, and animal welfare.