• DocumentCode
    1099594
  • Title

    Dynamic proximity of spatio-temporal sequences

  • Author

    Horn, David ; Dror, Gideon ; Quenet, Brigitte

  • Author_Institution
    Sch. of Phys. & Astron., Tel Aviv Univ., Israel
  • Volume
    15
  • Issue
    5
  • fYear
    2004
  • Firstpage
    1002
  • Lastpage
    1008
  • Abstract
    Recurrent networks can generate spatio-temporal neural sequences of very large cycles, having an apparent random behavior. Nonetheless a proximity measure between these sequences may be defined through comparison of the synaptic weight matrices that generate them. Following the dynamic neural filter (DNF) formalism we demonstrate this concept by comparing teacher and student recurrent networks of binary neurons. We show that large sequences, providing a training set well exceeding the Cover limit, allow for good determination of the synaptic matrices. Alternatively, assuming the matrices to be known, very fast determination of the biases can be achieved. Thus, a spatio-temporal sequence may be regarded as spatio-temporal encoding of the bias vector. We introduce a linear support vector machine (SVM) variant of the DNF in order to specify an optimal weight matrix. This approach allows us to deal with noise. Spatio-temporal sequences generated by different DNFs with the same number of neurons may be compared by calculating correlations of the synaptic matrices of the reconstructed DNFs. Other types of spatio-temporal sequences need the introduction of hidden neurons, and/or the use of a kernel variant of the SVM approach. The latter is being defined as a recurrent support vector network (RSVN).
  • Keywords
    learning systems; matrix algebra; recurrent neural nets; spatiotemporal phenomena; support vector machines; Cover limit; bias vector spatio-temporal encoding; binary neurons; dynamic neural filter formalism; dynamic proximity; linear support vector machine; recurrent support vector network; spatio-temporal sequences; synaptic weight matrices; Astronomy; Binary sequences; Computer science; Encoding; Filters; Kernel; Neurons; Physics; Support vector machines; Symmetric matrices; Action Potentials; Algorithms; Animals; Artificial Intelligence; Central Nervous System; Humans; Linear Models; Nerve Net; Neural Networks (Computer); Neural Pathways; Neurons; Nonlinear Dynamics; Synapses; Synaptic Transmission; Time Factors;
  • fLanguage
    English
  • Journal_Title
    Neural Networks, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    1045-9227
  • Type

    jour

  • DOI
    10.1109/TNN.2004.832809
  • Filename
    1333065