Abstract
The shifted-Wald model is a popular analysis tool for one-choice reaction-time tasks. In its simplest version, the shifted-Wald model assumes a constant trial-independent drift rate parameter. However, the presence of endogenous processes—fluctuation in attention and motivation, fatigue and boredom—suggest that drift rate might vary across experimental trials. Here we show how across-trial variability in drift rate can be accounted for by assuming a trial-specific drift rate parameter that is governed by a positive-valued distribution. We consider two candidate distributions: the truncated normal distribution and the gamma distribution. For the resulting distributions of first-arrival times, we derive analytical and sampling-based solutions, and implement the models in a Bayesian framework. Recovery studies and an application to a data set comprised of 1469 participants suggest that (1) both mixture distributions yield similar results; (2) all model parameters can be recovered accurately except for the drift variance parameter; (3) despite poor recovery, the presence of the drift variance parameter facilitates accurate recovery of the remaining parameters; (4) shift, threshold, and drift mean parameters are correlated.
Highlights
Human decision-making has been studied using a large variety of experimental paradigms
The presence of endogenous processes, such as fluctuation in attention and motivation, fatigue and boredom, suggest that drift rate might vary across trials (Ratcliff & Strayer, 2014; Ratcliff & Tuerlinckx, 2002; Ratcliff & Van Dongen, 2011; Ratcliff & Van Zandt, 1999): “Parameters may change from day to day or from one block of trials to the
We compared whether the modes of the posterior distributions of the synthetic participants correspond to the data-generating values, and we considered the interquartile ranges of the posterior distributions to assess the uncertainty about the parameter values
Summary
Human decision-making has been studied using a large variety of experimental paradigms. We derive the distribution of the firstarrival times for the SW model assuming a trial-dependent drift rate parameter.
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