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Published on: August 11, 2016
Latitudinal variation in light levels drives human visual system size.
1Institute of Cognitive and Evolutionary Anthropology, University of Oxford, Oxford, UK. eiluned.pearce@anthro.ox.ac.uk
Human eyeball size increases with latitude, suggesting ambient light levels influence visual system evolution. Larger visual systems at higher latitudes compensate for lower light, maintaining visual acuity.
Area of Science:
- Human evolutionary biology
- Biological anthropology
- Comparative anatomy
Background:
- Ambient light levels are known to influence visual system size in other species, such as birds and primates.
- Light intensity and day length decrease with increasing latitude on Earth.
Purpose of the Study:
- To investigate whether ambient light levels also influence human visual system size.
- To examine the relationship between latitude and human orbital volume as an indicator of eyeball size.
Main Methods:
- Analysis of the relationship between absolute latitude and human orbital volume across populations.
- Assessment of visual acuity across different latitudes under full-daylight conditions.
Main Results:
- A significant positive correlation was found between absolute latitude and human orbital volume.
- Visual acuity remained constant across latitudes, even with reduced ambient light at higher latitudes.
Conclusions:
- Intraspecific variation in human visual system size is likely driven by ambient light levels.
- Larger visual systems at higher latitudes may have evolved to compensate for reduced light, preserving visual function.

