Audiovisual detection at different intensities and delays

Chandramouli Chandrasekaran, Steven Blurton, Matthias Gondan

    1 Citation (Scopus)

    Abstract

    In the redundant signals task, two target stimuli are associated with the same response. If both targets are presented together, redundancy gains are observed, as compared with single-target presentation. Different models explain these redundancy gains, including race and coactivation models (e.g., the Wiener diffusion superposition model, Schwarz, 1994, Journal of Mathematical Psychology, and the Ornstein Uhlenbeck diffusion superposition model, Diederich, 1995, Journal of Mathematical Psychology). In the present study, two monkeys performed a simple detection task with auditory, visual and audiovisual stimuli of different intensities and onset asynchronies. In its basic form, a Wiener diffusion superposition model provided only a poor description of the observed data, especially of the detection rate (i.e., accuracy or hit rate) for low stimulus intensity. We expanded the model in two ways, by (A) adding a temporal deadline, that is, restricting the evidence accumulation process to a stopping time, and (B) adding a second “nogo” barrier representing target absence. We present closed-form solutions for the mean absorption times and absorption probabilities for a Wiener diffusion process with a drift towards a single barrier in the presence of a temporal deadline (A), and numerically improved solutions for the two-barrier model (B). The best description of the data was obtained from the deadline model and substantially outperformed the two-barrier approach.
    Original languageEnglish
    JournalJournal of Mathematical Psychology
    Volume91
    Pages (from-to)159-175
    ISSN0022-2496
    DOIs
    Publication statusPublished - Aug 2019

    Keywords

    • Faculty of Social Sciences
    • Multisensory processing
    • Monkey
    • Decision-making
    • Wiener diffusion process
    • Reaction times

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