Abstract
Evidence accumulation models provide a dominant account of human decision-making, and have been particularly successful at explaining behavioral and neural data in laboratory paradigms using abstract, stationary stimuli. It has been proposed, but with limited in-depth investigation so far, that similar decision-making mechanisms are involved in tasks of a more embodied nature, such as movement and locomotion, by directly accumulating externally measurable sensory quantities of which the precise, typically continuously time-varying, magnitudes are important for successful behavior. Here, we leverage collision threat detection as a task which is ecologically relevant in this sense, but which can also be rigorously observed and modelled in a laboratory setting. Conventionally, it is assumed that humans are limited in this task by a perceptual threshold on the optical expansion rate-the visual looming-of the obstacle. Using concurrent recordings of EEG and behavioral responses, we disprove this conventional assumption, and instead provide strong evidence that humans detect collision threats by accumulating the continuously time-varying visual looming signal. Generalizing existing accumulator model assumptions from stationary to time-varying sensory evidence, we show that our model accounts for previously unexplained empirical observations and full distributions of detection response. We replicate a pre-response centroparietal positivity (CPP) in scalp potentials, which has previously been found to correlate with accumulated decision evidence. In contrast with these existing findings, we show that our model is capable of predicting the onset of the CPP signature rather than its buildup, suggesting that neural evidence accumulation is implemented differently, possibly in distinct brain regions, in collision detection compared to previously studied paradigms.
Highlights
Human decision-making is a long-standing research topic, spanning disciplines such as psychology, neuroscience, economics, and human factors [1,2,3,4,5]
Evidence accumulation models of decision-making propose that humans accumulate noisy sensory evidence over time up to a decision threshold. We demonstrate that this type of model can describe human behavior well in abstract, semi-static laboratory tasks, and in a task that is relevant to human movement in the real world
We show that a model directly accumulating the continuously time-varying visual looming of an approaching obstacle explains full probability distributions of when humans can detect this collision threat
Summary
Human decision-making is a long-standing research topic, spanning disciplines such as psychology, neuroscience, economics, and human factors [1,2,3,4,5]. Evidence accumulation models ( known as drift diffusion or sequential sampling models) have emerged as one dominant account, positing that decisions are made once noisy evidence has been integrated over time up to a decision threshold [6,7,8,9,10,11] These models have been successful at explaining distributions of behavioral choices and response times across numerous laboratory paradigms, e.g., where participants make categorization decisions about ambiguous stimuli, or choose between options with different subjective or objective value [6,7,8,9,10,11]. Computational modelling of evidence accumulation decision-making has so far focused on laboratory paradigms using stimuli that (i) have stationary or only intermittently and/or noisily changing saliency over time [7, 18, 20,21,22,23,24], and (ii) are abstract in nature, typically not mapping directly to any real-world task
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