Human visual performance changes with visual field location. It is best at the center of gaze
and declines with eccentricity, and also varies markedly with polar angle. These perceptual …

A central question in neuroscience is how the organization of cortical maps relates to
perception, for which human primary visual cortex (V1) is an ideal model system. V1 …

Human vision is heterogeneous around the visual field. At a fixed eccentricity, performance
is better along the horizontal than the vertical meridian and along the lower than the upper …

Human vision has striking radial asymmetries, with performance on many tasks varying
sharply with stimulus polar angle. Performance is generally better on the horizontal than …

Asymmetries in visual performance at isoeccentric locations are well-documented and
functionally important. At a fixed eccentricity, visual performance is best along the horizontal …

Population receptive field (pRF) models fit to fMRI data are used to non-invasively measure
retinotopic maps in human visual cortex, and these maps are a fundamental component of …

The science of visual perception has a long history of develo** quantitative, computational
models to explain and predict visual performance on a variety of tasks. These models have …

Human visual performance changes dramatically both across (eccentricity) and around
(polar angle) the visual field. Performance is better at the fovea, decreases with eccentricity …

Visual performance varies around the visual field. It is best near the fovea compared to the
periphery, and at iso-eccentric locations it is best on the horizontal, intermediate on the …

With every saccadic eye movement, humans bring new information into their fovea to be
processed with high visual acuity. Notably, perception is enhanced already before a relevant …