Using saturation rational function models to calculate yield adjustment factors across varied milking frequencies.
Xiao-Lin Wu, John Cole, Asha M Miles, Paul M VanRaden
Abstract
Open AccessMilking frequency significantly affects milk yield in dairy cows, with higher frequency generally leading to greater lactation yields. The increase follows a nonlinear pattern, showing diminishing returns and eventually reaching saturation as milking frequency rises. This study introduces a polynomial rational function model to derive yield adjustment factors across different milking frequencies. Formulated as a ratio of 2 polynomials, this model has 3 parameters to capture the initial increase in yield and the saturation rate, offering enhanced flexibility across various milking frequencies. We compared its performance to a recently proposed exponential rational function model. Both models demonstrated a good fit to varying milking frequency data up to 10× and satisfactorily predicted yield adjustment factors for milking frequencies where data were absent. The polynomial rational function model exhibited a higher accuracy (root mean square error [RMSE] = 0.004; R2 = 0.999), achieving greater accuracy across a broader range of varied milking frequencies, compared with the exponential rational function model (RMSE = 0.011; R2 = 0.994). Nevertheless, the latter model proved more robust to limited data coverage of milking frequencies. This study also evaluated the strategy of leveraging 2× milking data to derive yield adjustment factors across different frequencies. However, caution is advised when extrapolating far beyond the data-supported frequency range.