In insects, as in vertebrates, neuroanatomical, electrophysiological, and modelling studies
have provided insights regarding identities and connections among neurones that …

Based on comparative anatomical studies and electrophysiological experiments, we have
identified a conserved subset of neurons in the lamina, medulla, and lobula of dipterous …

Many arthropods, notably spiders, decapod crustaceans, and insects have excellent visual
systems that allow them to evaluate self-movement and environmental features in many …

Visual perception seems effortless to us, yet it is the product of elaborate signal processing
in intricate brain circuits. Apart from vertebrates, arthropods represent another major animal …

The Hassenstein–Reichardt autocorrelation model for motion computation was derived
originally from studies of optomotor turning reactions of beetles and further refined from …

The neural circuitry of motion processing in insects, as in primates, involves the segregation
of different types of visual information into parallel retinotopic pathways that subsequently …

In dipteran brains, a motion sensitive but color insensitive, pathway consists of large
diameter neurons, organized as a precise retinotopic map. Several cell classes can be …

Despite their miniature brains insects, such as flies, bees and wasps, are able to navigate by
highly erobatic flight maneuvers in cluttered environments. They rely on spatial information …

Evolution has equipped vertebrates and invertebrates with neural circuits that selectively
encode visual motion. While similarities in the computations performed by these circuits in …

Motion detection is an important computational task, since animals including humans
heavily rely on visual motion information during locomotion. When an animal moves through …