Suboptimality in perceptual decision making

Rahnev, Dobromir; Denison, Rachel

doi:10.1017/s0140525x18000936

Cited by 251 publications

(270 citation statements)

References 361 publications

(572 reference statements)

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“…Notably, children exhibited this behavior despite learning the mean locations of the underlying distributions, and having access to the reliability of the sensory information on each trial. This pattern of behavior is consistent with an inability to appropriately take each available source of information into account, which could be due to deficits in the computation of task-relevant variables (including likelihoods, priors, objective functions and decision rules), or limitations in the neural implementation or approximation of Bayesian inference (Drugowitsch, Wyart, Devauchelle, & Koechlin, 2016;Rahnev & Denison, 2018). Note that one can only combine information across multiple cues if one can keep track of which aspects of that information should be combined and under what conditions.…”

Section: Discussionsupporting

confidence: 55%

Young children combine sensory cues with learned information in a statistically efficient manner: But task complexity matters

Bejjanki

Randrup

Aslin

2019

Preprint

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Research Highlights• Young children are sensitive to, and can learn, environmental regularities. Can they also utilize such learned regularities in a statistically efficient manner?• We demonstrate that 6-7-year olds are capable of learning and utilizing regularities in a statistically efficient fashion, and in a manner indistinguishable from adult behavior.• However, variables such as task complexity can influence young children's behavior to a greater extent than that of adults, leading their behavior to look sub-optimal.• These findings have important implications for how we should interpret failures in young children's ability to carry out sophisticated computations. AbstractHuman adults are adept at mitigating the influence of sensory uncertainty on task performance by integrating sensory cues with learned prior information, in a Bayes-optimal fashion. Previous research has shown that young children and infants are sensitive to environmental regularities, and that the ability to learn and use such regularities is involved in the development of several cognitive abilities. However, it has also been reported that children younger than 8 do not combine simultaneously available sensory cues in a Bayes-optimal fashion. Thus, it remains unclear whether, and by what age, children can combine sensory cues with learned regularities in an adult manner. Here, we examine the performance of 6-7-year old children when tasked with localizing a 'hidden' target by combining uncertain sensory information with prior information learned over repeated exposure to the task. We demonstrate that 6-7-year olds learn task-relevant statistics at a rate on-par with adults, and like adults, are capable of integrating learned regularities with sensory information in a statistically efficient manner. We also show that variables such as task complexity can influence young children's behavior to a greater extent than that of adults, leading their behavior to look sub-optimal. Our findings have important implications for how we should interpret failures in young children's ability to carry out sophisticated computations. These 'failures' need not be attributed to deficits in the fundamental computational capacity available to children early in development, but rather to ancillary immaturities in general cognitive abilities that mask the operation of these computations in specific situations.

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Section: Discussionsupporting

confidence: 55%

Young children combine sensory cues with learned information in a statistically efficient manner: But task complexity matters

Bejjanki

Randrup

Aslin

2019

Preprint

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“…These priors may vary between individuals, but are stable for a given individual, and reflect idiosyncratic biases. These are often unknown to the experimenter and hence may be shadowed by experimental manipulations or may be regarded as interindividual noise that is eliminated during data analysis (Kanai & Rees, 2011;Wexler, Duyck, & Mamassian, 2015;Rahnev & Denison, 2018;Lebovich, Darshan, Lavi, Hansel, & Loewenstein, 2019). We here argue that such inter-individual variability in temporary and idiosyncratic biases provides key perspectives on the neural mechanisms underlying perception.…”

Section: Introductionmentioning

confidence: 87%

Alpha Activity Reflects the Magnitude of an Individual Bias in Human Perception

Grabot

Kayser

2019

Preprint

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Biases in sensory perception can arise from both experimental manipulations and personal traitlike features. These idiosyncratic biases and their neural underpinnings are often overlooked in studies on the physiology underlying perception. A potential candidate mechanism mediating such idiosyncratic biases is spontaneous alpha activity, a prominent brain rhythm known to influence the processing of upcoming information in general. Using a time perception task, we here tested the hypothesis that alpha power reflects the compensation for an idiosyncratic bias. Importantly, to understand the interplay between idiosyncratic biases and contextual (temporary) biases induced by experimental manipulations, we quantified this relation before and after temporal recalibration. Using EEG recordings in human participants, we found that pre-stimulus alpha power correlates with the tendency to respond relative to an own idiosyncratic bias, with stronger alpha leading to responses matching the bias. In contrast, alpha power did not predict response correctness. These results also held after temporal recalibration and were specific to the alpha band, suggesting that alpha power indexes the cognitive effort to overcome an individual's momentary bias in perception. Significance statementThe brain is a biased organ, frequently generating systematically distorted percepts of the world, leading each of us to evolve in our own subjective reality. However, such biases are often overlooked or considered noise when studying the neural mechanisms underlying perception. We show that spontaneous alpha band activity predicts the degree of biasedness of human choices in a time perception task, suggesting that alpha power indexes the effort needed to overcome an individual's idiosyncratic bias. This result provides a window onto the neural underpinnings of subjective perception, and offers the possibility to quantify or manipulate such priors in future studies.

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“…The level of activity can then be used as a measure of uncertainty, and confidence levels can be based on this level. Such confidence ratings will be less informative than the perceptual decision, which is exactly what has been observed in a number of studies 2,28,29 . In addition, this type of confidence generation may explain findings that confidence tends to be biased towards the level of the evidence for the chosen stimulus category and tends to ignore the level of evidence against the chosen category [30][31][32][33][34][35] .…”

Section: Discussionmentioning

confidence: 52%

“…We sought to confirm and generalize these findings in two additional, pre-registered experiments. For Experiment 2, we made several modifications: (1) we changed the stimulus from color to symbols, (2) we raised the number of stimulus categories from four to six, and (3) we significantly increased the number of trials per subject in order to obtain stronger results on the individual-subject level. Specifically, we presented the six symbols '?…”

Section: Methodsmentioning

confidence: 99%

The suboptimality of perceptual decision making with multiple alternatives

Yeon

Rahnev

2019

Preprint

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It is becoming widely appreciated that human perceptual decision making is suboptimal but the nature and origins of this suboptimality remain poorly understood. Most past research has employed tasks with two stimulus categories, but such designs cannot fully capture the limitations inherent in naturalistic perceptual decisions where choices are rarely between only two alternatives. We conducted four experiments with tasks involving multiple alternatives and used computational modeling to determine the decision-level representation on which the perceptual decisions were based. The results from all four experiments pointed to the existence of robust suboptimality such that most of the information in the sensory representation was lost during the transformation to a decision-level representation. These results reveal severe limits in the quality of decision-level representations for multiple alternatives and have strong implications about perceptual decision making in naturalistic settings.

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Suboptimality in perceptual decision making

Cited by 251 publications

References 361 publications

Young children combine sensory cues with learned information in a statistically efficient manner: But task complexity matters

Young children combine sensory cues with learned information in a statistically efficient manner: But task complexity matters

Alpha Activity Reflects the Magnitude of an Individual Bias in Human Perception

The suboptimality of perceptual decision making with multiple alternatives

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