Inclusion bayes factors for mixed hierarchical diffusion decision models

Udo Böhm; Nathan Evans; Quentin Frederik Gronau; Dora Matzke; Eric-Jan Wagenmakers; Andrew Heathcote

doi:10.31234/osf.io/45t2w

Inclusion bayes factors for mixed hierarchical diffusion decision models

Udo Böhm^*
, Nathan Evans
, Quentin Frederik Gronau
, Dora Matzke
, Eric-Jan Wagenmakers
, Andrew Heathcote

^*Corresponding author for this work

Research output: Contribution to journal › Article › Scientific › peer-review

Abstract

Cognitive models provide a substantively meaningful quantitative description of latent cognitive processes. The quantitative formulation of these models supports cumulative theory building and enables strong empirical tests. However, the non-linearity of these models and pervasive correlations among model parameters pose special challenges when applying cognitive models to data. Firstly, estimating cognitive models typically requires large hierarchical data sets that need to be accommodated by an appropriate statistical structure within the model. Secondly, statistical inference needs to appropriately account for model uncertainty to avoid overconfidence and biased parameter estimates. In the present work we show how these challenges can be addressed through a combination ofBayesian hierarchical modelling and Bayesian model averaging. To illustrate these techniques, we apply the popular diffusion decision model to data from a collaborative selective influence study.

Original language	English
Pages (from-to)	625-655
Journal	Psychological Methods
Volume	29
Issue number	4
DOIs	https://doi.org/10.31234/osf.io/45t2w https://doi.org/10.1037/met0000582
Publication status	Published - Aug 2024
Externally published	Yes

Keywords

diffusion model
Bayes factors
response time daya

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title = "Inclusion bayes factors for mixed hierarchical diffusion decision models",

abstract = "Cognitive models provide a substantively meaningful quantitative description of latent cognitive processes. The quantitative formulation of these models supports cumulative theory building and enables strong empirical tests. However, the non-linearity of these models and pervasive correlations among model parameters pose special challenges when applying cognitive models to data. Firstly, estimating cognitive models typically requires large hierarchical data sets that need to be accommodated by an appropriate statistical structure within the model. Secondly, statistical inference needs to appropriately account for model uncertainty to avoid overconfidence and biased parameter estimates. In the present work we show how these challenges can be addressed through a combination ofBayesian hierarchical modelling and Bayesian model averaging. To illustrate these techniques, we apply the popular diffusion decision model to data from a collaborative selective influence study.",

keywords = "diffusion model, Bayes factors, response time daya",

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AU - Evans, Nathan

AU - Gronau, Quentin Frederik

AU - Matzke, Dora

AU - Wagenmakers, Eric-Jan

AU - Heathcote, Andrew

PY - 2024/8

Y1 - 2024/8

N2 - Cognitive models provide a substantively meaningful quantitative description of latent cognitive processes. The quantitative formulation of these models supports cumulative theory building and enables strong empirical tests. However, the non-linearity of these models and pervasive correlations among model parameters pose special challenges when applying cognitive models to data. Firstly, estimating cognitive models typically requires large hierarchical data sets that need to be accommodated by an appropriate statistical structure within the model. Secondly, statistical inference needs to appropriately account for model uncertainty to avoid overconfidence and biased parameter estimates. In the present work we show how these challenges can be addressed through a combination ofBayesian hierarchical modelling and Bayesian model averaging. To illustrate these techniques, we apply the popular diffusion decision model to data from a collaborative selective influence study.

AB - Cognitive models provide a substantively meaningful quantitative description of latent cognitive processes. The quantitative formulation of these models supports cumulative theory building and enables strong empirical tests. However, the non-linearity of these models and pervasive correlations among model parameters pose special challenges when applying cognitive models to data. Firstly, estimating cognitive models typically requires large hierarchical data sets that need to be accommodated by an appropriate statistical structure within the model. Secondly, statistical inference needs to appropriately account for model uncertainty to avoid overconfidence and biased parameter estimates. In the present work we show how these challenges can be addressed through a combination ofBayesian hierarchical modelling and Bayesian model averaging. To illustrate these techniques, we apply the popular diffusion decision model to data from a collaborative selective influence study.

KW - diffusion model

KW - Bayes factors

KW - response time daya

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VL - 29

SP - 625

EP - 655

JO - Psychological Methods

JF - Psychological Methods

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ER -

Inclusion bayes factors for mixed hierarchical diffusion decision models

Abstract

Keywords

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