# Inferring behavioural states from tracking data with hidden Markov models – a validation study using GPS video-camera collars

**Authors:** Benjamin Larue, Jonathan J. Farr, Libby Ehlers, Jim Herriges, Torsten Bentzen, Michael J. Suitor, Kyle Joly, Théo Michelot, Barbara Vuillaume, Steeve D. Côté, Eliezer Gurarie, Mark Hebblewhite

PMC · DOI: 10.1186/s40462-025-00621-x · 2026-01-24

## TL;DR

This study validates the use of hidden Markov models (HMMs) to infer animal behavior from GPS data by comparing them to video observations in caribou.

## Contribution

The study empirically validates HMM-inferred behaviors in caribou and highlights the impact of GPS sampling frequency on accuracy.

## Key findings

- HMM-inferred states often mismatch observed behaviors, especially at longer GPS sampling intervals.
- Foraging behaviors are hardest to infer accurately due to variable movement patterns.
- Behavioral states inferred from GPS data vary across different temporal resolutions.

## Abstract

Hidden Markov models (HMMs) are increasingly used to infer animal behavioural states from GPS tracking data, yet their interpretation often remains uncertain in the absence of empirical validation. Misinterpretation of statistical states as biologically meaningful behaviours can undermine scientific understanding and conservation decisions. Our objective was to evaluate how well HMM-inferred states correspond to directly observed behaviours and to test how the temporal resolution of GPS sampling influences behavioural inference.

We used GPS collars equipped with video cameras to validate HMM-inferred behavioural states in 81 female migratory caribou (Rangifer tarandus) from two herds. We compared states derived from two- and three-state HMMs to behaviours observed in short collar video clips. To assess the effect of temporal scale, we fit HMMs to GPS data resampled at 20-, 60-, and 120-minute relocation intervals.

HMM-inferred behavioural states frequently diverged from video-observed behaviours at the start of observed GPS steps, especially at longer relocation intervals. These mismatches appeared to result from overlapping movement metrics among caribou behaviours (e.g., foraging vs. resting or traveling) and the inability of coarser GPS data to capture behavioural switches occurring at finer temporal scales than the fix rate. Videos of eating were the most misaligned with HMM-inferred states, likely due to high variation in caribou movement while foraging that is often characteristic of mixed-feeding large herbivores. Inferred states for a given location were often inconsistent across temporal scales, indicating that HMM outputs must be interpreted cautiously with respect to the GPS sampling frequency.

The predicted HMM state can differ substantially from true behaviour at the start of each step, in particular at coarse temporal scales. Our results serve as a reminder to interpret HMM states over whole steps rather than at observed positions, validate movement-derived states where possible, and align sampling resolution with species-specific behavioural patterns.

The online version contains supplementary material available at 10.1186/s40462-025-00621-x.

## Linked entities

- **Species:** Rangifer tarandus (taxon 9870)

## Full-text entities

- **Diseases:** HMM (MESH:D004195)
- **Chemicals:** FAUNE-16 (-)
- **Species:** Panthera leo (lion, species) [taxon 9689], Myotis vivesi (fish-eating bat, species) [taxon 233766], Morus bassanus (northern gannet, species) [taxon 37578], Rangifer tarandus (caribou, species) [taxon 9870], Chiroptera (bats, order) [taxon 9397]

## Figures

4 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12924397/full.md

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Source: https://tomesphere.com/paper/PMC12924397