Probing cross modal interactions in the perception of object motion and self-motion. How the brain integrates information from the different senses is not yet understood. This project aims first, to uncover how the brain integrates sound and visual information when perceiving moving objects and second, to probe more complex sensory interactions between sound, vision, and our vestibular senses when perceiving self-motion. This project will expand Australia's knowledge base, strengthen collabora ....Probing cross modal interactions in the perception of object motion and self-motion. How the brain integrates information from the different senses is not yet understood. This project aims first, to uncover how the brain integrates sound and visual information when perceiving moving objects and second, to probe more complex sensory interactions between sound, vision, and our vestibular senses when perceiving self-motion. This project will expand Australia's knowledge base, strengthen collaborative ties between Australia and Japan, and provide unique training opportunities for Australian and Japanese students. Publication of research in top-ranking journals will further promote Australian science abroad. Results will lead to improvements in the design of human-machine interfaces in both industry and entertainment.Read moreRead less
Visuomotor Adaptation and Stimulus Response Compatibility: Basic Mechanisms and Safety Implications for Heavy Equipment. This project will explore mechanisms of human visuomotor adaptation using a directional stimulus-response compatibility (SRC) paradigm. The latter refers to the greatly enhanced performance for ?natural? pairings of control movement directions and system output directions. The outcomes are both theoretical (understanding basic processes) and applied (design and training gui ....Visuomotor Adaptation and Stimulus Response Compatibility: Basic Mechanisms and Safety Implications for Heavy Equipment. This project will explore mechanisms of human visuomotor adaptation using a directional stimulus-response compatibility (SRC) paradigm. The latter refers to the greatly enhanced performance for ?natural? pairings of control movement directions and system output directions. The outcomes are both theoretical (understanding basic processes) and applied (design and training guidelines for equipment in construction, mining, transport and aerospace industries). The issue is also significant both theoretically, since models of adaptation and SRC phenomena have not previously been combined, and practically, as serious heavy equipment accidents can result from designs that are not based on sound human performance principles.Read moreRead less