A Mathematical Model for the Action Spectrum of Steady-State Pupil Size in Photopic Vision with Insight into Healthful Lighting

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Summary

This study proposes a new mathematical model describing how both melanopsin-driven (intrinsic) ipRGC signals and cone-driven (extrinsic) signals jointly regulate steady-state pupil size under continuous photopic lighting, using a large hemisphere LED screen for realistic architectural simulation. A key practical implication is that extrinsic cone signals—previously underestimated—become increasingly important at lower melanopic radiance levels, meaning lighting designers cannot rely solely on melanopic metrics to predict pupillary and nonvisual responses.

Key Findings

Both intrinsic (ipRGC/melanopsin) and extrinsic (cone-driven) signals contribute to steady-state pupil size regulation under continuous photopic lighting conditions.
Extrinsic signal contribution increases as melanopic radiance decreases in photopic conditions, suggesting prior models underestimated the role of cone-driven signals at lower light intensities.
A new mathematical model was developed to calculate the relative contributions of intrinsic and extrinsic signals to melanopic radiance-driven pupil responses, enabling more accurate prediction of nonvisual lighting effects in buildings.

Categories

The Science of Light: Develops a mathematical model for steady-state pupil size action spectrum, quantifying intrinsic (ipRGC) and extrinsic (cone-driven) contributions to the pupillary light reflex under continuous photopic lighting.

Eye Health & Vision: Examines pupillary light reflex as a noninvasive indicator of retinal and autonomic nervous system function, with implications for visual comfort and adaptation in architectural spaces.