A Mixed-Filter Algorithm for Dynamically Tracking Learning from Multiple Behavioral and Neurophysiological Measures

Todd P. Coleman, Marianna Yanike, Wendy Suzuki, Emery N. Brown

Research output: Chapter in Book/Report/Conference proceedingChapter

Abstract

Learning is a dynamic process generally defined as a change in behavior as a result of experience. Behavioral performance is commonly measured with continuous variables (reaction times) as well as binary variables (correct/incorrect task execution). When neural activity is recorded at the same time as behavioral measures, an important question is the extent to which neural correlates can be associated with the changes in behavior. Recent work has combined subsets of the three aforementioned modalities to understand learning. In this work, we develop an analysis of learning within a state-space framework of simultaneously recorded continuous and binary performance measures along with neural spiking activity modeled as a point process. This chapter illustrates our approach in the analysis of a simulated learning experiment, and an actual learning experiment, in which a monkey rapidly learns new associations within a single session.

Original languageEnglish (US)
Title of host publicationThe Dynamic Brain: An Exploration of Neuronal Variability and Its Functional Significance
PublisherOxford University Press
ISBN (Print)9780199897049, 9780195393798
DOIs
StatePublished - Sep 22 2011

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Filter
Experiment
Modality
Monkey
Reaction Time
Performance Measures
Neural Correlates

Keywords

  • Behavioral measures
  • Cognitive state
  • Learning
  • Neurophysiology
  • Recursive filter
  • State-space model

ASJC Scopus subject areas

  • Arts and Humanities(all)

Cite this

Coleman, T. P., Yanike, M., Suzuki, W., & Brown, E. N. (2011). A Mixed-Filter Algorithm for Dynamically Tracking Learning from Multiple Behavioral and Neurophysiological Measures. In The Dynamic Brain: An Exploration of Neuronal Variability and Its Functional Significance Oxford University Press. https://doi.org/10.1093/acprof:oso/9780195393798.003.0001

A Mixed-Filter Algorithm for Dynamically Tracking Learning from Multiple Behavioral and Neurophysiological Measures. / Coleman, Todd P.; Yanike, Marianna; Suzuki, Wendy; Brown, Emery N.

The Dynamic Brain: An Exploration of Neuronal Variability and Its Functional Significance. Oxford University Press, 2011.

Research output: Chapter in Book/Report/Conference proceedingChapter

Coleman, TP, Yanike, M, Suzuki, W & Brown, EN 2011, A Mixed-Filter Algorithm for Dynamically Tracking Learning from Multiple Behavioral and Neurophysiological Measures. in The Dynamic Brain: An Exploration of Neuronal Variability and Its Functional Significance. Oxford University Press. https://doi.org/10.1093/acprof:oso/9780195393798.003.0001
Coleman TP, Yanike M, Suzuki W, Brown EN. A Mixed-Filter Algorithm for Dynamically Tracking Learning from Multiple Behavioral and Neurophysiological Measures. In The Dynamic Brain: An Exploration of Neuronal Variability and Its Functional Significance. Oxford University Press. 2011 https://doi.org/10.1093/acprof:oso/9780195393798.003.0001
Coleman, Todd P. ; Yanike, Marianna ; Suzuki, Wendy ; Brown, Emery N. / A Mixed-Filter Algorithm for Dynamically Tracking Learning from Multiple Behavioral and Neurophysiological Measures. The Dynamic Brain: An Exploration of Neuronal Variability and Its Functional Significance. Oxford University Press, 2011.
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