Perceptual asynchronies between color and motion at the onset of motion and along the motion trajectory

A color change that is physically simultaneous with the onset of object motion may be perceived as occurring before the initial displacement. In contrast, a colored flash during object motion is displaced in the direction of motion, suggesting that it is perceived after the continuous position change. The aim of our study was to reconcile these apparently conflicting results. To this end, we reexamined color-motion asynchronies as a function of trajectory position. Our results indicate that an abrupt color change lags object motion along the trajectory, but no asynchrony was found when the abrupt color change occurred at motion onset. Even if the lag of color relative to motion decreased with increasing object size, we did not replicate a lag of motion relative to color in any of our experiments. Furthermore, judgments at motion onset were not correlated with judgments along the trajectory, suggesting that the underlying mechanisms or task demands were different. Temporal order may be judged at motion onset, whereas position is judged during ongoing motio

Local motion inside an object affects pointing less than smooth pursuit

During smooth pursuit eye movements, briefly presented objects are mislocalized in the direction of motion. It has been proposed that the localization error is the sum of the pursuit signal and the retinal motion signal in a ~200ms interval after flash onset. To evaluate contributions of retinal motion signals produced by the entire object (global motion) and elements within the object (local motion), we asked observers to reach to flashed Gabor patches (Gaussian-windowed sine-wave gratings). Global motion was manipulated by varying the duration of a stationary flash, and local motion was manipulated by varying the motion of the sine-wave. Our results confirm that global retinal motion reduces the localization error. The effect of local retinal motion on object localization was far smaller, even though local and global motion had equal effects on eye velocity. Thus, local retinal motion has differential access to manual and oculomotor control circuits. Further, we observed moderate correlations between smooth pursuit gain and localization erro

Multivariate Cutoff Level Analysis (MultiCoLA) of large community data sets

High-throughput sequencing techniques are becoming attractive to molecular biologists and ecologists as they provide a time- and cost-effective way to explore diversity patterns in environmental samples at an unprecedented resolution. An issue common to many studies is the definition of what fractions of a data set should be considered as rare or dominant. Yet this question has neither been satisfactorily addressed, nor is the impact of such definition on data set structure and interpretation been fully evaluated. Here we propose a strategy, MultiCoLA (Multivariate Cutoff Level Analysis), to systematically assess the impact of various abundance or rarity cutoff levels on the resulting data set structure and on the consistency of the further ecological interpretation. We applied MultiCoLA to a 454 massively parallel tag sequencing data set of V6 ribosomal sequences from marine microbes in temperate coastal sands. Consistent ecological patterns were maintained after removing up to 35–40% rare sequences and similar patterns of beta diversity were observed after denoising the data set by using a preclustering algorithm of 454 flowgrams. This example validates the importance of exploring the impact of the definition of rarity in large community data sets. Future applications can be foreseen for data sets from different types of habitats, e.g. other marine environments, soil and human microbiota

Misbindings between abrupt and continuous changes : a unified explanation for the flash-lag effect and perceptual asynchronies

Bien que motivées par différents contextes de recherche, les illusions du flash-lag et des asynchronies perceptives pourraient être considérées comme la manifestation d'un problème général auquel est confronté le système perceptif. Ce problème est de pouvoir lier des changements abrupts à des changements continus. Lorsque ces changements se produisent dans la même dimension perceptive, comme dans l'illusion du flash–lag, le changement abrupt (flash) est erronément lié au changement continu (mouvement) de telle sorte qu'il est perçu retardé. Nous avons montré que la dynamique des erreurs de liages pouvait expliquer les erreurs perceptives lorsque deux objets en mouvement devaient être localisés. Lorsque les changements abrupts et continus se produisent entre les dimensions perceptives, comme dans les asynchronies perceptives, un abrupt changement de couleur durant la trajectoire d'un objet en mouvement est perçu retardé, tandis qu'au départ de la trajectoire, aucune erreur de liage ne se manifeste de manière consistante