Episode

An Inference-Based Architecture for Intent and Affordance Saturation in Decision-Making

Wendyam Eric Lionel Ilboudo,Saori C Tanaka

Dec 29, 2025•10:06

Neurons and CognitionArtificial IntelligenceMachine Learning

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Abstract

Decision paralysis, i.e. hesitation, freezing, or failure to act despite full knowledge and motivation, poses a challenge for choice models that assume options are already specified and readily comparable. Drawing on qualitative reports in autism research that are especially salient, we propose a computational account in which paralysis arises from convergence failure in a hierarchical decision process. We separate intent selection (what to pursue) from affordance selection (how to pursue the goal) and formalize commitment as inference under a mixture of reverse- and forward-Kullback-Leibler (KL) objectives. Reverse KL is mode-seeking and promotes rapid commitment, whereas forward KL is mode-covering and preserves multiple plausible goals or actions. In static and dynamic (drift-diffusion) models, forward-KL-biased inference yields slow, heavy-tailed response times and two distinct failure modes, intent saturation and affordance saturation, when values are similar. Simulations in multi-option tasks reproduce key features of decision inertia and shutdown, treating autism as an extreme regime of a general, inference-based, decision-making continuum.

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View on arXiv Download PDF

Authors

Wendyam Eric Lionel Ilboudo Saori C Tanaka

Cite This Paper

arXiv:2512.23144

Year:2025

Category:q-bio.NC

APA

Ilboudo, W. E. L., Tanaka, S. C. (2025). An Inference-Based Architecture for Intent and Affordance Saturation in Decision-Making. arXiv preprint arXiv:2512.23144.

MLA

Wendyam Eric Lionel Ilboudo and Saori C Tanaka. "An Inference-Based Architecture for Intent and Affordance Saturation in Decision-Making." arXiv preprint arXiv:2512.23144 (2025).