As we move through our environment, the flow of the deforming images o
n our retinae provides rich information about ego motion and about the
three-dimensional structure of the external world, Flow-fields compri
se five independent compenents, including radial and circular motion(1
-3). Here we provide psychophysical evidence for the existence of neur
al mechanisms in human vision that integrate motion signals along thes
e complex trajectories, Signal-to-noise sensitivity for discriminating
the direction of radial, circular and translational motion increased
predictably with the number of exposed sectors, implying the existence
of specialized detectors that integrate motion signals of different d
irections from different locations, However, contrast sensitivity for
complex motion did not increase greatly with sector number, implying t
hat the specialized detectors are preceded by a first stage of local-m
otion mechanisms that impose a contrast threshold. These findings fit
well with recent electrophysiological evidence in monkey(4-7) showing
that whereas motion-sensitive neurons in primary visual cortex respond
best to local translation, many neurons in the medial superior tempor
al cortex have large receptive fields tuned to radial, circular or spi
ral motion.