Conceptual Organization is Revealed by Consumer Activity Patterns

Hornsby, Adam N.; Evans, Thomas; Riefer, Peter S.; Prior, Rosie; Love, Bradley C.

doi:10.1007/s42113-019-00064-9

Cited by 16 publications

(15 citation statements)

References 27 publications

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“…This specification states that, assuming that two processes can execute the decision in a strictly independent manner with distinct RT distributions, the observed distribution of RTs is a mixture of those distributions, and all mixture proportions should share a common density point. Consistent with prior work in perceptual decision-making [63,64], we found no evidence for a fixed-point under the different levels of time pressure. Note, however, that the fixed-point test is a conservative test, with conservative assumptions: if, in addition to the change in the mixture proportion, time pressure affects some other aspect of the data then the fixed-point property may not apply, even though the actual true generative process is a mixture of processes [35,36].…”

Section: Plos Onesupporting

confidence: 87%

Investigating the origin and consequences of endogenous default options in repeated economic choices

2020

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Classical value-based decision theories state that economic choices are solely based on the value of available options. Experimental evidence suggests, however, that individuals' choices are biased towards default options, prompted by the framing of decisions. Although the effects of default options created by exogenous framing-such as how choice options are displayed-are well-documented, little is known about the potential effects and properties of endogenous framing, that is, originating from an individual's internal state. In this study, we investigated the existence and properties of endogenous default options in a task involving choices between risky lotteries. By manipulating and examining the effects of three experimental features-time pressure, time spent on task and relative choice proportion towards a specific option-, we reveal and dissociate two features of endogenous default options which bias individuals' choices: a natural tendency to prefer certain types of options (natural default), and the tendency to implicitly learn a default option from past choices (learned default). Additional analyses suggest that while the natural default may bias the standard choice process towards an option category, the learned default effects may be attributable to a second independent choice process. Overall, these investigations provide a first experimental evidence of how individuals build and apply diverse endogenous default options in economic decision-making and how this biases their choices.

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Section: Plos Onesupporting

confidence: 87%

Investigating the origin and consequences of endogenous default options in repeated economic choices

2020

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“…Some believe the replication crisis is a measure of the scientific quality of a sub-field, and given that it has affected areas of psychology with less formal modeling, one possibility might be to ask these areas to model explicitly. By extension, modelers can begin to publish more in these areas (e.g., in consumer behaviour, see Hornsby, Evans, Riefer, Prior, & Love, 2019).…”

Section: A Way Forwardmentioning

confidence: 99%

How Computational Modeling Can Force Theory Building in Psychological Science

Guest

Martin

2021

Perspect Psychol Sci

308

260

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Psychology endeavors to develop theories of human capacities and behaviors on the basis of a variety of methodologies and dependent measures. We argue that one of the most divisive factors in psychological science is whether researchers choose to use computational modeling of theories (over and above data) during the scientific-inference process. Modeling is undervalued yet holds promise for advancing psychological science. The inherent demands of computational modeling guide us toward better science by forcing us to conceptually analyze, specify, and formalize intuitions that otherwise remain unexamined—what we dub open theory. Constraining our inference process through modeling enables us to build explanatory and predictive theories. Here, we present scientific inference in psychology as a path function in which each step shapes the next. Computational modeling can constrain these steps, thus advancing scientific inference over and above the stewardship of experimental practice (e.g., preregistration). If psychology continues to eschew computational modeling, we predict more replicability crises and persistent failure at coherent theory building. This is because without formal modeling we lack open and transparent theorizing. We also explain how to formalize, specify, and implement a computational model, emphasizing that the advantages of modeling can be achieved by anyone with benefit to all.

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“…In widely reported behaviors in behavioral economics, people’s choices tend to show temporal dependencies across multiple time-scales [ 49 ]. While these behaviors have been previously regarded merely as “anomalies” [ 50 , 51 ], it may be more natural to think that multiscale processing has evolutionary significance beyond the narrowly-defined rational theories of behavior that assume an independence between trials that is unlikely in the real world [ 52 , 53 , 54 , 55 ].…”

Section: Introductionmentioning

confidence: 99%

Multiscale Computation and Dynamic Attention in Biological and Artificial Intelligence

2020

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Biological and artificial intelligence (AI) are often defined by their capacity to achieve a hierarchy of short-term and long-term goals that require incorporating information over time and space at both local and global scales. More advanced forms of this capacity involve the adaptive modulation of integration across scales, which resolve computational inefficiency and explore-exploit dilemmas at the same time. Research in neuroscience and AI have both made progress towards understanding architectures that achieve this. Insight into biological computations come from phenomena such as decision inertia, habit formation, information search, risky choices and foraging. Across these domains, the brain is equipped with mechanisms (such as the dorsal anterior cingulate and dorsolateral prefrontal cortex) that can represent and modulate across scales, both with top-down control processes and by local to global consolidation as information progresses from sensory to prefrontal areas. Paralleling these biological architectures, progress in AI is marked by innovations in dynamic multiscale modulation, moving from recurrent and convolutional neural networks—with fixed scalings—to attention, transformers, dynamic convolutions, and consciousness priors—which modulate scale to input and increase scale breadth. The use and development of these multiscale innovations in robotic agents, game AI, and natural language processing (NLP) are pushing the boundaries of AI achievements. By juxtaposing biological and artificial intelligence, the present work underscores the critical importance of multiscale processing to general intelligence, as well as highlighting innovations and differences between the future of biological and artificial intelligence.

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Conceptual Organization is Revealed by Consumer Activity Patterns

Cited by 16 publications

References 27 publications

Investigating the origin and consequences of endogenous default options in repeated economic choices

Investigating the origin and consequences of endogenous default options in repeated economic choices

How Computational Modeling Can Force Theory Building in Psychological Science

Multiscale Computation and Dynamic Attention in Biological and Artificial Intelligence

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