The photopic sensitivity of the yellow field of the pigeon's retina to ultraviolet light.

The photopic spectral sensitivity of the yellow field of the pigeon's retina to UV light was determined electrophysiologically. The sensitivity curve could be approximated with a model in which the activity of only two cone types were incorporated. In this model, the first type of cone had a maximum sensitivity at 366 nm and was combined with an oil droplet that is completely transparent in the UV wavelength range. The second type had a sensitivity maximum at 415 nm and was associated with an oil droplet cutting off light below 390 nm.

The relation between celestial colour gradients and the position of the sun, with regard to the sun compass.

Colour gradients along the sky caused by atmospheric scattering were measured on sunny days. It is concluded that whereas the shape of the spectral intensity distribution in the short wavelength range is stable, the distribution at longer wavelengths depends on the direction of measurement. We expressed these relative intensity differences as a spectral contrast. This contrast plotted as a function of angular difference with respect to the position of the sun establishes a smooth gradient. We suggest that the pigeon's UV sensitivity is part of a colour processing system, which is well adapted to employ these gradients in order to derive the sun's position.

Artificial lighting in poultry houses: do hens perceive the modulation of fluorescent lamps as flicker?

1. Many poultry houses are illuminated by fluorescent lamps which produce discontinuous illumination with a frequency of either 100 or 120 Hz. 2. This study investigated whether domestic fowls perceive this discontinuity as flicker by training two Leghorn hens to choose between a continuous and a discontinuous light, all other variables being identical. 3. The light-stimulus was either monochromatic with 100% sinusoidal modulation or a fluorescent lamp whose modulation frequency could be electrically adjusted. 4. Each (correct) choice for the discontinuous light was followed by a 5 Hz higher frequency, whereas an incorrect choice was followed by a 10 Hz lower frequency. 5. On the basis of this principle the animals themselves established the highest perceivable frequency of the discontinuous light, called the Critical Fusion Frequency (CFF), that they could discriminate from continuous light. 6. These frequencies typically depend on the stimulus intensity increasing with increasing intensities, until a maximum value is reached. 7. Two factors limited the magnitudes of the CFF's that were recorded: the maximum stimulus intensities produced and variability in the chicken's response ("behavioural noise"). In spite of these constraints 105 Hz was established as the maximum CFF. 8. On the basis of extrapolation it is concluded that the direct light from fluorescent lamps driven by 50 Hz alternating current is seen by the chicken as flickering. 9. The results justify large-scale comparison of behaviour and production in poultry houses that are illuminated either by low-frequency or by high-frequency fluorescent lamps.