An Expert Guide to Planning Experimental Tasks For Evidence-Accumulation Modeling

Russell J. Boag; Reilly J. Innes; Niek Stevenson; Giwon Bahg; Jerome R. Busemeyer; Gregory E. Cox; Chris Donkin; Michael J. Frank; Guy E. Hawkins; Andrew Heathcote; Craig Hedge; Veronika Lerche; Simon D. Lilburn; Gordon D. Logan; Dora Matzke; Steven Miletić; Adam F. Osth; Thomas J. Palmeri; Per B. Sederberg; Henrik Singmann; Philip L. Smith; Tom Stafford; Mark Steyvers; Luke Strickland; Jennifer S. Trueblood; Konstantinos Tsetsos; Brandon M. Turner; Marius Usher; Leendert van Maanen; Don van Ravenzwaaij; Joachim Vandekerckhove; Andreas Voss; Emily R. Weichart; Gabriel Weindel; Corey N. White; Nathan J. Evans; Scott D. Brown; Birte U. Forstmann

doi:10.1177/25152459251336127

An Expert Guide to Planning Experimental Tasks For Evidence-Accumulation Modeling

Russell J. Boag^*, Reilly J. Innes, Niek Stevenson, Giwon Bahg, Jerome R. Busemeyer, Gregory E. Cox, Chris Donkin, Michael J. Frank, Guy E. Hawkins, Andrew Heathcote, Craig Hedge, Veronika Lerche, Simon D. Lilburn, Gordon D. Logan, Dora Matzke, Steven Miletić, Adam F. Osth, Thomas J. Palmeri, Per B. Sederberg, Henrik SingmannPhilip L. Smith, Tom Stafford, Mark Steyvers, Luke Strickland, Jennifer S. Trueblood, Konstantinos Tsetsos, Brandon M. Turner, Marius Usher, Leendert van Maanen, Don van Ravenzwaaij, Joachim Vandekerckhove, Andreas Voss, Emily R. Weichart, Gabriel Weindel, Corey N. White, Nathan J. Evans, Scott D. Brown, Birte U. Forstmann

^*Corresponding author for this work

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Abstract

Evidence-accumulation models (EAMs) are powerful tools for making sense of human and animal decision-making behavior. EAMs have generated significant theoretical advances in psychology, behavioral economics, and cognitive neuroscience and are increasingly used as a measurement tool in clinical research and other applied settings. Obtaining valid and reliable inferences from EAMs depends on knowing how to establish a close match between model assumptions and features of the task/data to which the model is applied. However, this knowledge is rarely articulated in the EAM literature, leaving beginners to rely on the private advice of mentors and colleagues and inefficient trial-and-error learning. In this article, we provide practical guidance for designing tasks appropriate for EAMs, relating experimental manipulations to EAM parameters, planning appropriate sample sizes, and preparing data and conducting an EAM analysis. Our advice is based on prior methodological studies and the our substantial collective experience with EAMs. By encouraging good task-design practices and warning of potential pitfalls, we hope to improve the quality and trustworthiness of future EAM research and applications.

Original language	English
Number of pages	41
Journal	Advances in Methods and Practices in Psychological Science
Volume	8
Issue number	2
Early online date	27 May 2025
DOIs	https://doi.org/10.1177/25152459251336127
Publication status	Published - 27 May 2025

Bibliographical note

Copyright © The Author(s) 2025. This article is distributed under the terms of the Creative Commons Attribution 4.0 License (https://creativecommons.org/licenses/by/4.0/) which permits any use, reproduction and distribution of the work without further permission provided the original work is attributed as specified on the SAGE and Open Access pages (https://us.sagepub.com/en-us/nam/open-access-at-sage).

Funding

R. J. Boag, R. J. Innes, N. Stevenson, and B. U. Forstmann were supported by a European Research Council Consolidator Grant (864750) and NWO Vici (016.Vici.185.052) awarded to B. U. Forstmann. N. J. Evans was supported by an Australian Research Council Discovery Early Career Researcher Award (DE200101130). S. D. Brown was supported by Australian Research Council Discovery Project grants (DP210100313 and DP210103873). G. Bagh, S. D. Lilburn, G. D. Logan, and T. J. Palmeri were supported by National Institutes of Health Grant NEI R01-EY021833. D. Matzke and A. Heathcote were supported by a Vidi grant (VI.Vidi.191.091) from the Dutch Research Council. A. Heathcote was supported by and Australia-US Multi-University Research Initiative grant (DSTG AUS-MURIV000003, ONR/DoD N00014-23-1-2792).

Keywords

evidence-accumulation models
experimental design
decision-making
response time
model-based cognitive neuroscience

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10.1177/25152459251336127Licence: CC BY 4.0

boag-et-al-2025-an-expert-guide-to-planning-experimental-tasks-for-evidence-accumulation-modeling
Copyright © The Author(s) 2025. This article is distributed under the terms of the Creative Commons Attribution 4.0 License (https://creativecommons.org/licenses/by/4.0/) which permits any use, reproduction and distribution of the work without further permission provided the original work is attributed as specified on the SAGE and Open Access pages (https://us.sagepub.com/en-us/nam/open-access-at-sage).
Final published version, 1.23 MBLicence: CC BY 4.0

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Boag, R. J., Innes, R. J., Stevenson, N., Bahg, G., Busemeyer, J. R., Cox, G. E., Donkin, C., Frank, M. J., Hawkins, G. E., Heathcote, A., Hedge, C., Lerche, V., Lilburn, S. D., Logan, G. D., Matzke, D., Miletić, S., Osth, A. F., Palmeri, T. J., Sederberg, P. B., ... Forstmann, B. U. (2025). An Expert Guide to Planning Experimental Tasks For Evidence-Accumulation Modeling. Advances in Methods and Practices in Psychological Science, 8(2). https://doi.org/10.1177/25152459251336127

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abstract = "Evidence-accumulation models (EAMs) are powerful tools for making sense of human and animal decision-making behavior. EAMs have generated significant theoretical advances in psychology, behavioral economics, and cognitive neuroscience and are increasingly used as a measurement tool in clinical research and other applied settings. Obtaining valid and reliable inferences from EAMs depends on knowing how to establish a close match between model assumptions and features of the task/data to which the model is applied. However, this knowledge is rarely articulated in the EAM literature, leaving beginners to rely on the private advice of mentors and colleagues and inefficient trial-and-error learning. In this article, we provide practical guidance for designing tasks appropriate for EAMs, relating experimental manipulations to EAM parameters, planning appropriate sample sizes, and preparing data and conducting an EAM analysis. Our advice is based on prior methodological studies and the our substantial collective experience with EAMs. By encouraging good task-design practices and warning of potential pitfalls, we hope to improve the quality and trustworthiness of future EAM research and applications.",

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Boag, RJ, Innes, RJ, Stevenson, N, Bahg, G, Busemeyer, JR, Cox, GE, Donkin, C, Frank, MJ, Hawkins, GE, Heathcote, A, Hedge, C, Lerche, V, Lilburn, SD, Logan, GD, Matzke, D, Miletić, S, Osth, AF, Palmeri, TJ, Sederberg, PB, Singmann, H, Smith, PL, Stafford, T, Steyvers, M, Strickland, L, Trueblood, JS, Tsetsos, K, Turner, BM, Usher, M, van Maanen, L, van Ravenzwaaij, D, Vandekerckhove, J, Voss, A, Weichart, ER, Weindel, G, White, CN, Evans, NJ, Brown, SD & Forstmann, BU 2025, 'An Expert Guide to Planning Experimental Tasks For Evidence-Accumulation Modeling', Advances in Methods and Practices in Psychological Science, vol. 8, no. 2. https://doi.org/10.1177/25152459251336127

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AU - Innes, Reilly J.

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AU - Busemeyer, Jerome R.

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AU - van Ravenzwaaij, Don

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AU - White, Corey N.

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N2 - Evidence-accumulation models (EAMs) are powerful tools for making sense of human and animal decision-making behavior. EAMs have generated significant theoretical advances in psychology, behavioral economics, and cognitive neuroscience and are increasingly used as a measurement tool in clinical research and other applied settings. Obtaining valid and reliable inferences from EAMs depends on knowing how to establish a close match between model assumptions and features of the task/data to which the model is applied. However, this knowledge is rarely articulated in the EAM literature, leaving beginners to rely on the private advice of mentors and colleagues and inefficient trial-and-error learning. In this article, we provide practical guidance for designing tasks appropriate for EAMs, relating experimental manipulations to EAM parameters, planning appropriate sample sizes, and preparing data and conducting an EAM analysis. Our advice is based on prior methodological studies and the our substantial collective experience with EAMs. By encouraging good task-design practices and warning of potential pitfalls, we hope to improve the quality and trustworthiness of future EAM research and applications.

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An Expert Guide to Planning Experimental Tasks For Evidence-Accumulation Modeling

Abstract

Bibliographical note

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Keywords

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