Reaction time to motion onset and magnitude estimation of velocity in the presence of background motion

Unattended and attended visual change detection of motion as indexed by event-related potentials and its behavioral correlates

Visual mismatch negativity (vMMN) is a negative-going component amongst cognitive event-related potentials. It reflects an automatic change-detection process that occurs when an infrequent stimulus is presented that is incongruent with the representation of a frequent (standard) event. In our research we use visual motion (more specifically motion direction changes) to study vMMN. Since movement in the visual field is quite irresistible to our brain, the question in hand is, if the detection of motion direction changes is dependent on attention directed to the stimulus. We present a new continuous whole-display stimulus configuration, where the attention capturing primary task of motion onset detection is in the central part of the visual display and visual oddball sequence on the background. The visual oddball paradigm consisted of 85% standard and 15% deviant events, motion direction change being the deviant. We show that even though the unattended visual oddball sequence does not affect the performance in the demanding behavioral primary task, the differences appearing in that sequence are noticed by our brain and reflected in two distinguishable vMMN components in occipital and parietal scalp locations. When attention is directed toward the visual oddball sequence, we only see different processing of standards and deviants in later time-windows and task-related activity in frontal scalp location. Our results are obtained under strict attention manipulation conditions.

Investigation of center-surround interaction in motion with reaction time for direction discrimination

How motion onset asynchrony (MOA) alters the effects of stimulus size on reaction time (RT) for direction discrimination of a drifting grating was examined. MOA is a delay from the stimulus onset to the onset of motion. Without MOA, RTs were found to increase as the stimulus size was increased at high contrast, but decrease with it at low contrast or at high noise levels. With MOA, however, RTs did not increase as the stimulus size increased even at high contrast. These results suggest that sudden stimulus onset evokes the increase of RTs with the increase of stimulus size at high contrast. RTs for direction discrimination of a drifting Gabor patch (the target) surrounded by a different drifting or a static grating as well as RTs for the target that was not surrounded by an additional grating were measured. The RTs for the target moving in the same or opposite direction as the motion of the surrounding grating were larger than those for the target with the static grating or no additional grating at moderate or high contrast. There was no significant difference between the RTs for the target moving in the same direction as the surrounding grating and the RTs for the target moving in the opposite direction. At low contrast and without MOA, however, the RTs for the target moving in the same direction as the surrounding grating were larger than those for the target moving in the opposite direction. These results suggest surround suppression at low contrast under some conditions. They also suggest that the decrease of RTs for discriminating motion direction of a drifting single Gabor patch with the increase of stimulus size at low contrast does not necessarily mean the absence of surround suppression.