The Perception of Globally Coherent Motion

How do human observers perceive a coherent pattern of motion from a disparate set of local motion measures? Our research has examined how ambiguous motion signals along straight contours are spatially integrated to obtain a globally coherent perception of motion. Observers viewed displays containing a large number of apertures, with each aperture containing one or more contours whose orientations and velocities could be independently specified. The total pattern of the contour trajectories across the individual apertures was manipulated to produce globally coherent motions, such as rotations, expansions, or translations. For displays containing only straight contours extending to the circumferences of the apertures, observers' reports of global motion direction were biased whenever the sampling of contour orientations was asymmetric relative to the direction of motion. Performance was improved by the presence of identifiable features, such as line ends or crossings, whose trajectories could be tracked over time. The reports of our observers were consistent with a pooling process involving a vector average of measures of the component of velocity normal to contour orientation, rather than with the predictions of the intersection-of-constraints analysis in velocity space.Air Force Office of Scientific Research (90-0175, 89-0016); National Science Foundation, Office of Naval Research, Air Force Office of Scientific Research (BNS-8908426

Aging and the visual perception of exocentric distance

AbstractThe ability of 18 younger and older adults to visually perceive exocentric distances was evaluated. The observers judged the extent of fronto-parallel and in-depth spatial intervals at a variety of viewing distances from 50cm to 164.3cm. Most of the observers perceived in-depth intervals to be significantly smaller than fronto-parallel intervals, a finding that is consistent with previous studies. While none of the individual observers’ judgments of exocentric distance were accurate, the judgments of the older observers were significantly more accurate than those of the younger observers. The precision of the observers’ judgments across repeated trials, however, was not affected by age. The results demonstrate that increases in age can produce significant improvements in the visual ability to perceive the magnitude of exocentric distances

Five Lenses on Team Tutor Challenges: A Multidisciplinary Approach

This chapter describes five disciplinary domains of research or lenses that contribute to the design of a team tutor. We focus on four significant challenges in developing Intelligent Team Tutoring Systems (ITTSs), and explore how the five lenses can offer guidance for these challenges. The four challenges arise in the design of team member interactions, performance metrics and skill development, feedback, and tutor authoring. The five lenses or research domains that we apply to these four challenges are Tutor Engineering, Learning Sciences, Science of Teams, Data Analyst, and Human–Computer Interaction. This matrix of applications from each perspective offers a framework to guide designers in creating ITTSs

The importance of contours for visual object recognition and discrimination

Em contraste com muitos sistemas artificiais de visão, nós, observadores humanos, podemos reconhecer prontamente objetos sólidos e discriminar visualmente suas formas 3-D, mesmo sob mudanças no ponto de vista e variações na orientação e iluminação do objeto. Embora a importância da disparidade binocular seja conhecida desde a década de 1830, a relevância e a riqueza perceptiva das informações fornecidas pelos contornos visuais para o reconhecimento e discriminação de objetos não são devidamente apreciadas. Este artigo revisará as contribuições científicas que demonstram que os contornos visuais e suas deformações ao longo do tempo (em resposta ao movimento do objeto ou do observador) proporcionam tanto ou mais informações sobre a forma do objeto do que outras formas de informação visual.A diferencia de los sistemas de visión artificial, los observadores humanos pueden reconocer fácilmente objetos sólidos y discriminar visualmente su forma 3D, incluso cuando se producen cambios en su punto de vista, en la orientación o en la iluminación. Aunque la importancia de la disparidade binocular es conocida desde 1830, la relevancia y la riqueza de la información provista por los contornos visuales para el reconocimiento y discriminación de los objetos no ha sido apreciada adecuadamente. En este artículo se revisan las contribuciones científicas que demuestran que los contornos visuales y sus deformaciones a lo largo del tiempo (en respuesta a los movimentos tanto del observador como del objeto) proporcionan tanto o más información sobre la forma del objeto que otros tipos de información visual.In contrast to many machine vision systems, we human observers can readily recognize solid objects and visually discriminate their 3-D shapes even under changes in viewpoint and variations in object orientation and lighting.  While the importance of binocular disparity has been known since the 1830's, the importance and perceptual informativeness of visual contours for object recognition and discrimination is not adequately appreciated.  This article will review those scientific contributions that demonstrate that visual contours and their deformations over time (in response to object or observer motion) carry as much or more information about object shape than other forms of visual information