An Overcomplete Approach to Fitting Drift-Diffusion Decision Models to Trial-By-Trial Data

Feltgen, Q. and Daunizeau, J. (2021) An Overcomplete Approach to Fitting Drift-Diffusion Decision Models to Trial-By-Trial Data. Frontiers in Artificial Intelligence, 4. ISSN 2624-8212

[thumbnail of pubmed-zip/versions/2/package-entries/frai-04-531316.pdf] Text
pubmed-zip/versions/2/package-entries/frai-04-531316.pdf - Published Version

Download (4MB)

Abstract

Drift-diffusion models or DDMs are becoming a standard in the field of computational neuroscience. They extend models from signal detection theory by proposing a simple mechanistic explanation for the observed relationship between decision outcomes and reaction times (RT). In brief, they assume that decisions are triggered once the accumulated evidence in favor of a particular alternative option has reached a predefined threshold. Fitting a DDM to empirical data then allows one to interpret observed group or condition differences in terms of a change in the underlying model parameters. However, current approaches only yield reliable parameter estimates in specific situations (c.f. fixed drift rates vs drift rates varying over trials). In addition, they become computationally unfeasible when more general DDM variants are considered (e.g., with collapsing bounds). In this note, we propose a fast and efficient approach to parameter estimation that relies on fitting a “self-consistency” equation that RT fulfill under the DDM. This effectively bypasses the computational bottleneck of standard DDM parameter estimation approaches, at the cost of estimating the trial-specific neural noise variables that perturb the underlying evidence accumulation process. For the purpose of behavioral data analysis, these act as nuisance variables and render the model “overcomplete,” which is finessed using a variational Bayesian system identification scheme. However, for the purpose of neural data analysis, estimates of neural noise perturbation terms are a desirable (and unique) feature of the approach. Using numerical simulations, we show that this “overcomplete” approach matches the performance of current parameter estimation approaches for simple DDM variants, and outperforms them for more complex DDM variants. Finally, we demonstrate the added-value of the approach, when applied to a recent value-based decision making experiment.

Item Type: Article
Subjects: Scholar Eprints > Multidisciplinary
Depositing User: Managing Editor
Date Deposited: 03 Apr 2023 05:37
Last Modified: 05 Sep 2024 11:56
URI: http://repository.stmscientificarchives.com/id/eprint/1057

Actions (login required)

View Item
View Item