Neural network models of conditioning and action

The result of a conference held at Harvard University, this volume presents some of the exciting interdisciplinary developments that are clarifying how animals and people learn to behave adaptively in a rapidly changing environment. The text focuses on aspects of how recognition learning, reinforcement learning, and motor learning interact to generate adaptive goal-oriented behaviors that can satisfy internal needs -- an important topic for understanding brain function as well as for designing new types of autonomous robots. Because a dynamic analysis of system interactions is needed to understand these challenging phenomena -- and neural network models provide a natural framework for representing and analyzing such interactions -- all the articles either develop neural network models or provide biological constraints for guiding and testing their design. The result of a conference held at Harvard University, this volume presents some of the exciting interdisciplinary developments that clarify how animals and people learn to behave adaptively in a rapidly changing environment. The contributors focus on aspects of how recognition learning, reinforcement learning, and motor learning interact to generate adaptive goal-oriented behaviors that can satisfy internal needs -- an area of inquiry as important for understanding brain function as it is for designing new types of autonomous robots. Because a dynamic analysis of system interactions is needed to understand these challenging phenomena -- and neural network models provide a natural framework for representing and analyzing such interactions -- all the articles either develop neural network models or provide biological constraints for guiding and testing their design.

Contents: M.L. Commons, S. Grossberg, J.E.R. Staddon, Preface. Part I:Models of Classical Conditioning. D.L. Alkon, T.P. Vogl, K.T. Blackwell, D. Tam, Memory Function in Neural and Artificial Networks. D.A. Baxter, D.V. Buonomano, J.L. Raymond, D.G. Cook, F.M. Kuenzi, T.J. Carew, J.H. Byrne, Empirically Derived Adaptive Elements and Networks Simulate Associative Learning. W.B. Levy, C.M. Colbert, Adaptive Synaptogenesis Can Complement Associate Potentiation/Depression. S. Grossberg, A Neural Network Architecture for Pavlovian Conditioning: Reinforcement, Attention, Forgetting, Timing. D.S. Levine, P.S. Prueitt, Simulations of Conditioned Perseveration and Novelty Preference from Frontal Lobe Damage. N.A. Schmajuk, J.J. DiCarlo, Neural Dynamics of Hippocampal Modulation of Classical Conditioning. J.W. Moore, Implementing Connectionist Algorithms for Classical Conditioning in the Brain. Part II:Models of Instrumental Conditioning. M.L. Commons, E.W. Bing, C.C. Griffy, E.J. Trudeau, Models of Acquisition and Preference. R.M. Church, H.A. Broadbent, A Connectionist Model of Timing. W.S. Maki, A.M. Abunawass, A Connectionist Approach to Conditional Discriminations: Learning, Short-Term Memory, and Attention. J.E.R. Staddon, Y. Zhang, On the Assignment-of-Credit Problem in Operant Learning. S.J. Hanson, Behavioral Diversity, Search and Stochastic Connectionist Systems.