Learning representations in a gated prefrontal cortex model of dynamic task switching

&
Cognitive Science 26 (4):503-520 (2002)
  Copy   BIBTEX

Abstract

The prefrontal cortex is widely believed to play an important role in facilitating people's ability to switch performance between different tasks. We present a biologically‐based computational model of prefrontal cortex (PFC) that explains its role in task switching in terms of the greater flexibility conferred by activation‐based working memory representations in PFC, as compared with more slowly adapting weight‐based memory mechanisms. Specifically we show that PFC representations can be rapidly updated when a task switches via a dynamic gating mechanism based on a temporal‐differences reward‐prediction learning mechanism. Unlike prior models of this type, the present model develops all of its internal representations via learning mechanisms as shaped by the demands of continuous periodic task switching. This advance opens up a new domain of research into the interactions between working memory task demands and the representations that develop to meet them. Results on a version of the Wisconsin card sorting task are presented for the full model and a number of comparison networks that test the importance of various model features. Furthermore, we show that a lesioned model produces perseverative errors like those seen in frontal patients.

Categories

Add categories

Keywords

Reprint years

DOI

10.1207/s15516709cog2604_4

Links

PhilArchive



    Upload a copy of this work     Papers currently archived: 91,386

External links

Setup an account with your affiliations in order to access resources via your University's proxy server

Through your library

My notes

Similar books and articles

How does the attentional pointer work in prefrontal cortex?Naoyuki Osaka - 2003 - Behavioral and Brain Sciences 26 (6):751-751.
Autonomy in Action: Linking the Act of Looking to Memory Formation in Infancy via Dynamic Neural Fields.Sammy Perone & John P. Spencer - 2013 - Cognitive Science 37 (1):1-60.
When, What, and How Much to Reward in Reinforcement Learning-Based Models of Cognition.Christian P. Janssen & Wayne D. Gray - 2012 - Cognitive Science 36 (2):333-358.
Representational trajectories in connectionist learning.Andy Clark - 1994 - Minds and Machines 4 (3):317-32.
Autonomous Learning of Sequential Tasks: Experiments and Analyses.Todd Peterson - unknown
Are People Successful at Learning Sequences of Actions on a Perceptual Matching Task?Reiko Yakushijin & Robert A. Jacobs - 2011 - Cognitive Science 35 (5):939-962.
A subsymbolic symbolic model for learning sequential navigation.Ron Sun Todd Peterson - unknown
Working memory retention systems: A state of activated long-term memory.Daniel S. Ruchkin, Jordan Grafman, Katherine Cameron & Rita S. Berndt - 2003 - Behavioral and Brain Sciences 26 (6):709-728.
Self segmentation of sequences.Ron Sun - unknown
Quantifiers and Working Memory.Jakub Szymanik & Marcin Zajenkowski - 2010 - In Maria Aloni & Katrin Schulz (eds.), Amsterdam Colloquium 2009, LNAI 6042. Springer.
Dynamical learning algorithms for neural networks and neural constructivism.Enrico Blanzieri - 1997 - Behavioral and Brain Sciences 20 (4):559-559.
Learning to plan probabilistically from neural networks.R. Sun - unknown
Bidding in Reinforcement Learning: A Paradigm for Multi-Agent Systems.Chad Sessions - unknown

Analytics

Added to PP
2013-11-21

Downloads
14 (#965,243)

6 months
5 (#629,136)

Historical graph of downloads
How can I increase my downloads?

Citations of this work

Eye movements reveal dynamics of task control.Ulrich Mayr, David Kuhns & Miranda Rieter - 2013 - Journal of Experimental Psychology: General 142 (2):489.

Add more citations

References found in this work

An Integrative Theory of Prefrontal Cortex Function.Earl K. Miller & Jonathan D. Cohen - 2001 - Annual Review of Neuroscience 24 (1):167-202.
Finding Structure in Time.Jeffrey L. Elman - 1990 - Cognitive Science 14 (2):179-211.

View all 6 references / Add more references