Strategic and Dynamic Temporal Weighting for Perceptual Decisions in Humans and Macaques

Levi, Aaron J.; Yates, Jacob L.; Huk, Alexander C.; Katz, Leor N.

doi:10.1523/eneuro.0169-18.2018

Cited by 31 publications

(43 citation statements)

References 53 publications

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“…Previous studies have shown that a variety of species adapt their temporal weighting of evidence based on task demands. Humans and monkeys adopt temporal weighting of evidence to match learned temporal regularities of stimuli that are repeatedly presented, giving more weight to time periods with higher fidelity information (Levi et al, 2018). In that study, visual stimuli were presented for a fixed amount of time with no underlying variability in the time at which the information fidelity changed.…”

Section: Discussionmentioning

confidence: 99%

“…Shorter timescales are required for detecting changes in more volatile environments and when signal durations are briefer. Humans have been shown to adapt their timescale of evidence evaluation accordingly as a function of the distribution of signal durations and timing for visual stimuli (Tsetsos et al, 2012;Ossmy et al, 2013;Bronfman et al, 2016;Levi et al, 2018). Humans have also been shown to adapt their timescales of evidence evaluation in the optimal direction as a function of volatility when classifying source distributions for the location of visual stimuli (Glaze et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

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Timescales of Evidence Evaluation for Decision Making and Associated Confidence Judgments Are Adapted to Task Demands

et al. 2020

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Decision making often involves choosing actions based on relevant evidence. This can benefit from focussing evidence evaluation on the timescale of greatest relevance based on the situation. Here, we use an auditory change detection task to determine how people adjust their timescale of evidence evaluation depending on task demands for detecting changes in their environment and assessing their internal confidence in those decisions. We confirm previous results that people adopt shorter timescales of evidence evaluation for detecting changes in contexts with shorter signal durations, while bolstering those results with model-free analyses not previously used and extending the results to the auditory domain. We also extend these results to show that in contexts with shorter signal durations, people also adopt correspondingly shorter timescales of evidence evaluation for assessing confidence in their decision about detecting a change. These results provide important insights into adaptability and flexible control of evidence evaluation for decision making.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Timescales of Evidence Evaluation for Decision Making and Associated Confidence Judgments Are Adapted to Task Demands

et al. 2020

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“…Not surprisingly then, macaque visual performance has consistently been found to be close to that of humans (Buracas & Albright, 1999;Elmore & Wright, 2015;Gelfand & Horwitz, 2018;Harwerth, 1982;Kaas, 1992;Levi, Yates, Huk, & Katz, 2018;Lynn & Curran, 2010;Rajalingham, Schmidt, & DiCarlo, 2015;Zarco, Merchant, Prado, & Mendez, 2009). Macaques have also been shown to perceive multistable visual stimuli perceptually fluctuating with a temporal profile that is similar to that of humans (Dodd, Krug, Cumming, & F I G U R E 3 Evidence for perceptual rivalry in macaque.…”

Section: Primatesmentioning

confidence: 92%

Perceptual rivalry across animal species

Carter

Swinderen

Leopold

et al. 2020

J of Comparative Neurology

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“…Figure 1 demonstrates this alignment conceptually and the effect of 27 each type of choice model in this space. Specifically, for a population of only two 28 neurons, the joint activity of the population can be represented as points in a 2D space 29 where each axis represents an individual neuron's activity ( Figure 1A). For a 30 one-dimensional stimulus (as is typically used in discrimination paradigms), different 31 values of the stimulus (red and black) will drive activity that falls along a The choice is fed back and pushes variability along the stimulus axis.…”

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confidence: 99%

“…These results suggest the 76 monkeys' readout is either highly suboptimal or choice signal is fed back to sensory 77 cortex in the null space of the stimulus -multiplexing choice signals in sensory areas 78 without corrupting information about the stimulus. This feedback signal could be 79 critical for adapting sensory representations while learning new tasks or in 80 non-stationary environments [27,28].…”

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confidence: 99%

Stimulus-choice (mis)alignment in primate MT cortex

Zhao

Yates

Levi

et al. 2019

Preprint

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For stimuli near perceptual threshold, the trial-by-trial activity of single neurons in many sensory areas is correlated with the animal's perceptual report. This phenomenon has often been attributed to feedforward readout of the neural activity by the downstream decision-making circuits. The interpretation of choice-correlated activity is quite ambiguous, but its meaning can be better understood in the light of population-wide correlations among sensory neurons. Using a statistical nonlinear dimensionality reduction technique on single-trial ensemble recordings from the middle temporal area during perceptual-decision-making, we extracted low-dimensional neural trajectories that captured the population-wide fluctuations. We dissected the particular contributions of sensory-driven versus choice-correlated activity in the low-dimensional population code. We found that the neural trajectories strongly encoded the direction of the stimulus in single dimension with a temporal signature similar to that of single MT neurons. If the downstream circuit were optimally utilizing this information, choice-correlated signals should be aligned with this stimulus encoding dimension. Surprisingly, we found that a large component of the choice information resides in the subspace orthogonal to the stimulus representation inconsistent with the optimal readout view. This misaligned choice information allows the feedforward sensory information to coexist with the decision-making process. The time course of these signals suggest that this misaligned contribution likely is feedback from the downstream areas. We hypothesize that this non-corrupting choice-correlated feedback might be related to learning or reinforcing sensory-motor relations in the sensory population. Author summaryIn sensorimotor decision-making, internal representation of sensory stimuli is utilized for the generation of appropriate behavior for the context. Therefore, the correlation between variability in sensory neurons and perceptual decisions is sometimes explained by a causal, feedforward role of sensory noise in behavior. However, this correlation could also originate via feedback from decision-making mechanisms downstream of the sensory representation. This cannot be resolved by analyzing single unit responses, but requires a population level analysis. Area MT contains both sensory and choice information and is known to be the key sensory area for visual motion perception. Thus the decision-making process may be corrupting the sensory representation. However, we find that the sensory stimuli and choice variables are separate at the population level, Introduction 1 Sensory cortical neurons exhibit substantial variability to repeated presentations of the 2 same stimulus [1,2]. This variability depends on the specifics of the sensory stimulus 3 and task being performed [3][4][5][6][7], and is often correlated with the trial-by-trial perceptual 4 report of the animal [8][9][10][11]. This trial-by-trial correlation between neural responses and 5 perceptual reports, ...

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Strategic and Dynamic Temporal Weighting for Perceptual Decisions in Humans and Macaques

Cited by 31 publications

References 53 publications

Timescales of Evidence Evaluation for Decision Making and Associated Confidence Judgments Are Adapted to Task Demands

Timescales of Evidence Evaluation for Decision Making and Associated Confidence Judgments Are Adapted to Task Demands

Perceptual rivalry across animal species

Stimulus-choice (mis)alignment in primate MT cortex

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