Title :
Multidimensional density shaping by sigmoids
Author :
Roth, Ze´ew ; Baram, Yoram
Author_Institution :
Adv. Technol. Center, Qualcomm, Haifa, Israel
fDate :
9/1/1996 12:00:00 AM
Abstract :
An estimate of the probability density function of a random vector is obtained by maximizing the output entropy of a feedforward network of sigmoidal units with respect to the input weights. Classification problems can be solved by selecting the class associated with the maximal estimated density. Newton´s optimization method, applied to the estimated density, yields a recursive estimator for a random variable or a random sequence. A constrained connectivity structure yields a linear estimator, which is particularly suitable for “real time” prediction. A Gaussian nonlinearity yields a closed-form solution for the network´s parameters, which may also be used for initializing the optimization algorithm when other nonlinearities are employed. A triangular connectivity between the neurons and the input, which is naturally suggested by the statistical setting, reduces the number of parameters. Applications to classification and forecasting problems are demonstrated
Keywords :
Newton method; feedforward neural nets; function approximation; optimisation; probability; recursive estimation; Gaussian nonlinearity; Newton method; connectivity structure; feedforward neural network; function approximation; multidimensional density shaping; optimization; output entropy; probability density function; random vector; recursive estimation; sigmoids; triangular connectivity; Closed-form solution; Entropy; Multidimensional systems; Neurons; Optimization methods; Probability density function; Random sequences; Random variables; Recursive estimation; Yield estimation;
Journal_Title :
Neural Networks, IEEE Transactions on
