Title :
Generalization ability of folding networks
Author_Institution :
Dept. of Math. & Comput. Sci., Osnabruck Univ., Germany
Abstract :
The information theoretical learnability of folding networks, a very successful approach capable of dealing with tree structured inputs, is examined. We find bounds on the VC, pseudo-, and fat shattering dimension of folding networks with various activation functions. As a consequence, valid generalization of folding networks can be guaranteed. However, distribution independent bounds on the generalization error cannot exist in principle. We propose two approaches which take the specific distribution into account and allow us to derive explicit bounds on the deviation of the empirical error from the real error of a learning algorithm. The first approach requires the probability of large trees to be limited a priori and the second approach deals with situations where the maximum input height in a concrete learning example is restricted
Keywords :
generalisation (artificial intelligence); information theory; learning (artificial intelligence); probability; recurrent neural nets; transfer functions; activation functions; concrete learning example; distribution independent bounds; empirical error; explicit bounds; fat shattering dimension; folding networks; generalization ability; generalization error; information theoretical learnability; large trees; learning algorithm; maximum input height; real error; tree structured inputs; valid generalization; Classification tree analysis; Code standards; Computer networks; Concrete; Encoding; Neural networks; Recurrent neural networks; Tree data structures; Tree graphs; Virtual colonoscopy;
Journal_Title :
Knowledge and Data Engineering, IEEE Transactions on
