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Introduction to Radial Basis Function Networks. 主講人 : 虞台文. Content. Overview The Models of Function Approximator The Radial Basis Function Networks RBFN’s for Function Approximation The Projection Matrix Learning the Kernels Bias-Variance Dilemma The Effective Number of Parameters
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Content • Overview • The Models of Function Approximator • The Radial Basis Function Networks • RBFN’s for Function Approximation • The Projection Matrix • Learning the Kernels • Bias-Variance Dilemma • The Effective Number of Parameters • Model Selection • Incremental Operations
Typical Applications of NN • Pattern Classification • Function Approximation • Time-Series Forecasting
f ˆ f Function Approximation Unknown Approximator
+ + Supervised Learning Unknown Function Neural Network
Neural Networks as Universal Approximators • Feedforward neural networks with a single hidden layer of sigmoidal units are capable of approximating uniformly any continuous multivariate function, to any desired degree of accuracy. • Hornik, K., Stinchcombe, M., and White, H. (1989). "Multilayer Feedforward Networks are Universal Approximators," Neural Networks, 2(5), 359-366. • Like feedforward neural networks with a single hidden layer of sigmoidal units, it can be shown that RBF networks are universal approximators. • Park, J. and Sandberg, I. W. (1991). "Universal Approximation Using Radial-Basis-Function Networks," Neural Computation, 3(2), 246-257. • Park, J. and Sandberg, I. W. (1993). "Approximation and Radial-Basis-Function Networks," Neural Computation, 5(2), 305-316.
Introduction to Radial Basis Function Networks The Model of Function Approximator
Linear Models Weights Fixed Basis Functions
y w2 w1 wm 1 2 m x1 x2 xn x = Linear Models Linearly weighted output Output Units • Decomposition • Feature Extraction • Transformation Hidden Units Inputs Feature Vectors
Linear Models Can you say some bases? y Linearly weighted output Output Units w2 w1 wm • Decomposition • Feature Extraction • Transformation Hidden Units 1 2 m Inputs Feature Vectors x1 x2 xn x =
Example Linear Models Are they orthogonal bases? • Polynomial • Fourier Series
y w2 w1 wm 1 2 m x1 x2 xn x = Single-Layer Perceptrons as Universal Aproximators With sufficient number of sigmoidal units, it can be a universal approximator. Hidden Units
y w2 w1 wm 1 2 m x1 x2 xn x = Radial Basis Function Networks as Universal Aproximators With sufficient number of radial-basis-function units, it can also be a universal approximator. Hidden Units
Non-Linear Models Weights Adjusted by the Learning process
Introduction to Radial Basis Function Networks The Radial Basis Function Networks
Radial Basis Functions • Center • Distance Measure • Shape Three parameters for a radial function: i(x)= (||x xi||) xi r = ||x xi||
Typical Radial Functions • Gaussian • Hardy Multiquadratic • Inverse Multiquadratic
Inverse Multiquadratic c=5 c=4 c=3 c=2 c=1
+ + + Basis {i: i =1,2,…} is `near’ orthogonal. Most General RBF
Properties of RBF’s • On-Center, Off Surround • Analogies with localized receptive fields found in several biological structures, e.g., • visual cortex; • ganglion cells
y1 ym x1 x2 xn As a function approximator The Topology of RBF Output Units Interpolation Hidden Units Projection Inputs Feature Vectors
y1 ym x1 x2 xn As a pattern classifier. The Topology of RBF Output Units Classes Hidden Units Subclasses Inputs Feature Vectors
Introduction to Radial Basis Function Networks RBFN’s for Function Approximation
Unknown Function to Approximate Training Data The idea y x
Unknown Function to Approximate Training Data Basis Functions (Kernels) The idea y x
Function Learned Basis Functions (Kernels) The idea y x
Nontraining Sample Function Learned Basis Functions (Kernels) The idea y x
Nontraining Sample Function Learned The idea y x
w2 w1 wm x1 x2 xn x = Radial Basis Function Networks as Universal Aproximators Training set Goal for all k
w2 w1 wm x1 x2 xn x = Learn the Optimal Weight Vector Training set Goal for all k
Regularization Training set If regularization is unneeded, set Goal for all k
Learn the Optimal Weight Vector Minimize
Learn the Optimal Weight Vector Design Matrix Variance Matrix
Training set Summary
Introduction to Radial Basis Function Networks The Projection Matrix
Unknown Function The Empirical-Error Vector
Unknown Function The Empirical-Error Vector Error Vector
If =0, the RBFN’s learning algorithm is to minimizeSSE (MSE). Sum-Squared-Error Error Vector
The Projection Matrix Error Vector
Introduction to Radial Basis Function Networks Learning the Kernels
y1 yl wlml wl1 wl2 w1m w11 w12 2 m 1 x1 x2 xn RBFN’s as Universal Approximators Training set Kernels
y1 yl wlml wl1 wl2 w1m w11 w12 2 m 1 x1 x2 xn What to Learn? • Weightswij’s • Centers j’s of j’s • Widthsj’s of j’s • Number of j’s Model Selection
The simultaneous updates of all three sets of parameters may be suitable for non-stationary environments or on-line setting. One-Stage Learning