In this paper we propose a minimum α-information method to maximize and minimize information contained in hidden units. The method aims to interpret internal representations and to improve generalization performance. The α-information minimization forces hidden units to have maximum information or minimum information, depending on the importance of hidden units. To interpret internal representation, we have only to see a small number of hidden units with maximum information, ignoring hidden units with minimum information. In addition, by minimizing the α-information, unnecessary information can be eliminated, leading to better generalization. First, α-information was applied to a simple data compression problem in which four characters can be compressed into one hidden unit. Then we applied α-information minimization to one of the most challenging topics in neural networks, namely, the description and understanding of natural languages.As an example to demonstrate the acquisition of descriptive adequacy by neural networks, we dealt with the inference of well-formedness of an artificial language close to English. Experimental results confirmed that explicit internal representations can be obtained and generalization can be significantly improved. 1. Introduction. Many attempts have been made to describe learning by neural networks from the information theoretic point of view. Information has been maximized [12], [18]-[20] or minimized [1], [8], [13], depending on problems. Information maximization, applied to supervised learning, has been used to make hidden units respond clearly to input patterns [12]. Thus, it is easy to interpret interpretations. However, it is clear that information maximization cannot deal well with ambiguous input patterns, because hidden units must respond explicitly to any input pattern. By explicit responses to input patterns, improved generalization performance cannot be expected. To increase generalization performance, information has been minimized [1], [8], [13]. Information minimization prevents hidden units from responding too clearly to those input patterns.Thus, if information can be maximized and minimized at the same time, it is expected to have internal representations for better interpretation and improved generalization. The α-information is proposed to represent a situation in which information minimization and information maximization are both needed. When the α-information, represented in the difference between Shannon and Rényi entropy, is minimized, information can be maximized or minimized. Thus, α-information minimization performs an operation of information maximization and information minimization at the same time. Thus, the method can be used to interpret explicitly internal representations and to improve generalization.
