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Plants possess internal dynamics reflecting their environment. This study shows internal plant signals, like electrical activity and gas emissions, can predict plant affective states, demonstrating embodied environmental engagement.

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Area of Science:

  • Plant signaling
  • Affective computing
  • Machine learning in biology

Background:

  • Plants display complex internal dynamics in response to environmental changes.
  • The potential for these dynamics to represent structured affective states is largely unexplored.
  • Understanding plant responses can offer insights into non-animal affect.

Purpose of the Study:

  • To investigate if internal plant signals encode information about affective states.
  • To determine if machine learning models can decode these affective states using only internal plant measurements.
  • To explore the temporal dynamics of plant affective signaling.

Main Methods:

  • Utilized internal plant measurements: bioelectrical activity and volatile gas emissions.
  • Employed machine learning models for binary and multi-class classification of affective states.
  • Operationalized valence and arousal using environmental variables (temperature, humidity, light) but excluded them from model training.
  • Applied Echo State Networks to capture temporal dependencies in plant signals.

Main Results:

  • Machine learning models reliably decoded plant valence over longer temporal windows.
  • Plant arousal was decoded more effectively within shorter temporal windows, indicating distinct timescales.
  • Direct multi-class classification of affective quadrants was unstable, but temporal modeling improved performance.
  • Internal plant dynamics were shown to contain a learnable signature of affective regimes.

Conclusions:

  • Internal plant dynamics carry a learnable signature of environmentally defined affective regimes.
  • Plant affect can be interpreted as a form of embodied environmental engagement.
  • This research opens new avenues for understanding plant signaling and affective states.