70  Box A1   Animal Vision

  VetBooks.ir  Similar to visual acuity is accommodation,   that some animals, such as geckos and hawk-
                                                     moths, have special highly efficient cones to
            this is the eye’s ability to change its focal
            length so that objects at varying distances are
                                                     2006). In order to perceive colour the brain
            brought into focus. This is done by changing   allow colour vision at night (Kelber and Roth
            the shape of the lens, and also to some extent   compares the outputs of different classes of
            the shape of the eye itself. Thus as a general   cones, each maximally responsive to differ-
            rule, larger eyes have a greater range of   ent wavelengths of light. Humans have three
            accommodation than smaller ones. Large   cone types, and are thus referred to as tri-
            eyes provide long focal lengths and space for   chromats. As  a  general  rule,  animals  with
            a larger lens which in combination gives an   fewer cone types can distinguish fewer
            ability  for higher  resolution  over a  greater     colours. Our colour vision, and that of Old
            range of distances (Land and Nilsson 2012).   World monkeys and apes, is amongst the
            Differences in accommodation mean differ-  best found in mammals, since most mam-
            ences in the shortest distance at which an   mals are dichromats and have two classes of
            object can be brought into clear focus. Thus   cones and as such cannot distinguish as many
            humans with their greater accommodation   colours  as  we  can (Jacobs  1993). However
            can focus on an object just 7 cm away, whereas   birds, reptiles and amphibians typically have
            for a dog anything closer than 33–50 cm will   four types of cone which allows them to per-
            be blurred (Miller and Murphy 1995).     ceive a wider array of colours than we can.
              Colour is perhaps one of the most obvious   Often the more colourful a species is, the
            aspects of the world around us, yet few ani-  better its colour vision. However there are
            mals see it in the way we do. Colour vision   some exceptions. Cephalopods, well known
            typically requires cone cells, a special type of   for their colour‐based displays and camou-
            receptor cell in the retina. Cones normally   flage, are completely colour blind (Marshall
            require  higher  levels  of light to  function   and Messenger 1996) (Figure  A1.1). Some
            which is why we cannot see colour well in   species can use properties of light that we
            dim  light.  However  there  are some  excep-  cannot detect, such as ultraviolet wave-
            tions, for example it has recently been shown   lengths, the near infrared, or polarisation.



























            Figure A1.1  This broadclub cuttlefish, Sepia latimanis, like other cuttlefish has the ability to change colour yet
            is colour blind, so body colour itself is unlikely to be the visual signal which this species uses to communicate
            with one another. Source: Jeroen Stevens.