Response times from ensembles of accumulators

Zandbelt, Bram B.; Purcell, Braden A.; Palmeri, Thomas J.; Logan, Gordon D.; Schall, Jeffrey D.

doi:10.1073/pnas.1310577111

Cited by 59 publications

(65 citation statements)

References 49 publications

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“…However, it is unclear how EMG bounds incorporated into a single-model accumulator map onto activities of numerous accumulator neurons that encode confidence signals in the parietal cortex . The e pluribus unum model developed by Zandbelt et al (2014) sheds light on this issue. The model demonstrates that ensembles of numerous and redundant accumulator neurons can generate a RT distribution similar to that predicted by a single accumulator, provided that accumulation rates are moderately correlated and RT is not determined by the lowest and highest accumulation rates.…”

Section: Discussionmentioning

confidence: 99%

Using Covert Response Activation to Test Latent Assumptions of Formal Decision-Making Models in Humans

Servant

White

Montagnini

et al. 2015

Journal of Neuroscience

157

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Most decisions that we make build upon multiple streams of sensory evidence and control mechanisms are needed to filter out irrelevant information. Sequential sampling models of perceptual decision making have recently been enriched by attentional mechanisms that weight sensory evidence in a dynamic and goal-directed way. However, the framework retains the longstanding hypothesis that motor activity is engaged only once a decision threshold is reached. To probe latent assumptions of these models, neurophysiological indices are needed. Therefore, we collected behavioral and EMG data in the flanker task, a standard paradigm to investigate decisions about relevance. Although the models captured response time distributions and accuracy data, EMG analyses of response agonist muscles challenged the assumption of independence between decision and motor processes. Those analyses revealed covert incorrect EMG activity ("partial error") in a fraction of trials in which the correct response was finally given, providing intermediate states of evidence accumulation and response activation at the single-trial level. We extended the models by allowing motor activity to occur before a commitment to a choice and demonstrated that the proposed framework captured the rate, latency, and EMG surface of partial errors, along with the speed of the correction process. In return, EMG data provided strong constraints to discriminate between competing models that made similar behavioral predictions. Our study opens new theoretical and methodological avenues for understanding the links among decision making, cognitive control, and motor execution in humans.

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Section: Discussionmentioning

confidence: 99%

Using Covert Response Activation to Test Latent Assumptions of Formal Decision-Making Models in Humans

Servant

White

Montagnini

et al. 2015

Journal of Neuroscience

157

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“…This result, along with quantitatively superior model fits, lends strong support to the modeling of choice and confidence as a quantum random walk process, a model which describes decisionmaking as a constructive process wherein a definite state is created from an indefinite superposition. In addition to the cognitive implications, a QRW model of evidence accumulation potentially sidesteps the problem of how a group of neurons can produce observed behavior that is consistent with a single evidence accumulation trajectory (26). The QRW suggests that the mismatch might lie in the cognitive representation of evidence accumulation: instead of treating evidence accumulation as a single trajectory, it may be more accurate to conceptualize it as a wavelike superposition state.…”

Section: Discussionmentioning

confidence: 99%

Interference effects of choice on confidence: Quantum characteristics of evidence accumulation

Kvam

Pleskac

Sun

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

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Decision-making relies on a process of evidence accumulation which generates support for possible hypotheses. Models of this process derived from classical stochastic theories assume that information accumulates by moving across definite levels of evidence, carving out a single trajectory across these levels over time. In contrast, quantum decision models assume that evidence develops over time in a superposition state analogous to a wavelike pattern and that judgments and decisions are constructed by a measurement process by which a definite state of evidence is created from this indefinite state. This constructive process implies that interference effects should arise when multiple responses (measurements) are elicited over time. We report such an interference effect during a motion direction discrimination task. Decisions during the task interfered with subsequent confidence judgments, resulting in less extreme and more accurate judgments than when no decision was elicited. These results provide qualitative and quantitative support for a quantum random walk model of evidence accumulation over the popular Markov random walk model. We discuss the cognitive and neural implications of modeling evidence accumulation as a quantum dynamic system.ecisions in a wide range of tasks (e.g., inferring the presence or absence of a disease, the guilt or innocence of a suspect, and the left or right direction of enemy movement) require evidence to be accumulated in support of different hypotheses. Arguably, the most successful theory of evidence accumulation in humans and other animals is Markov random walk (MRW) theory (and diffusion models, their continuous space extensions) (1, 2). MRWs can be viewed as psychological implementations of a first-order Bayesian inference process that assigns a posterior probability to each hypothesis (3). MRWs can account for choices, response times, and confidence for a variety of different decision types (2, 4). Moreover, these models of the accumulation process have been connected to neural activity during decision-making (5, 6).According to MRW models, when deciding between two hypotheses, the cumulative evidence for or against each hypothesis realizes different levels at different times to generate a single particle-like trajectory of evidence levels across time (Fig. 1). At any point in time, the decision-maker has a definite level of evidence, and choices are made by comparing the existing level of evidence against a criterion. Evidence above the criterion favors one option, and evidence below it favors the alternative. Other responses are modeled in a similar manner; for example, confidence ratings are modeled by mapping evidence states onto one or more ratings (4). However, this idea that judgments and decisions are simply read out from the existing level of evidence-henceforth referred to as the "read-out" assumption-is inconsistent with the well-established idea that preferences and beliefs are constructed rather than revealed by judgments and decisions (7).We present an alternati...

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“…Recent studies have examined models for multi-alternative decision making that use diffusion processes [24,41,72,79-80,182-190] and a number of algorithms have been used: Independent racing accumulators with termination when one reaches its decision criterion.Independent racing accumulators with a relative stopping rule (termination occurs when one accumulator beats the maximum of the others by some amount).Accumulators with dependence between accumulators: inhibition between accumulators that depends on the amount of accumulated evidence.Accumulators with dependence: evidence for one alternative is evidence against the others so that the total evidence is constant. When one accumulator is incremented, the others are decremented (termed constant summed evidence or feedforward inhibition).…”

Section: Figurementioning

confidence: 99%

Diffusion Decision Model: Current Issues and History

Ratcliff

Smith

Brown

et al. 2016

Trends in Cognitive Sciences

1,383

1,481

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There is growing interest in diffusion models to represent the cognitive and neural processes of speeded decision making. Sequential-sampling models like the diffusion model have a long history in psychology. They view decision making as a process of noisy accumulation of evidence from a stimulus. The standard model assumes that evidence accumulates at a constant rate during the second or two it takes to make a decision. This process can be linked to the behaviors of populations of neurons and to theories of optimality. Diffusion models have been used successfully in a range of cognitive tasks and as psychometric tools in clinical research to examine individual differences. In this article, we relate the models to both earlier and more recent research in psychology.

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Response times from ensembles of accumulators

Cited by 59 publications

References 49 publications

Using Covert Response Activation to Test Latent Assumptions of Formal Decision-Making Models in Humans

Using Covert Response Activation to Test Latent Assumptions of Formal Decision-Making Models in Humans

Interference effects of choice on confidence: Quantum characteristics of evidence accumulation

Diffusion Decision Model: Current Issues and History

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