Semantic Information G Theory and Logical Bayesian Inference for Machine Learning

TL;DR

This paper introduces the G theory, Logical Bayesian Inference, and Channel Matching algorithms to improve multi-label machine learning, especially under changing prior distributions, with promising results in classification and mixture models.

Contribution

It proposes a novel semantic information G theory and Logical Bayesian Inference framework that simplifies learning functions and enhances multi-label classification performance.

Findings

High accuracy in three-class MMI classification with few iterations

Improved EM algorithm (CM-EM) for imbalanced mixture models

Neural network integration needed for high-dimensional spaces

Abstract

An important problem with machine learning is that when label number n>2, it is very difficult to construct and optimize a group of learning functions, and we wish that optimized learning functions are still useful when prior distribution P(x) (where x is an instance) is changed. To resolve this problem, the semantic information G theory, Logical Bayesian Inference (LBI), and a group of Channel Matching (CM) algorithms together form a systematic solution. A semantic channel in the G theory consists of a group of truth functions or membership functions. In comparison with likelihood functions, Bayesian posteriors, and Logistic functions used by popular methods, membership functions can be more conveniently used as learning functions without the above problem. In Logical Bayesian Inference (LBI), every label's learning is independent. For Multilabel learning, we can directly obtain a group of optimized membership functions from a big enough sample with labels, without preparing different samples for different labels. A group of Channel Matching (CM) algorithms is developed for machine learning. For the Maximum Mutual Information (MMI) classification of three classes with Gaussian distributions on a two-dimensional feature space, 2-3 iterations can make mutual information between three classes and three labels surpass 99% of the MMI for most initial partitions. For mixture models, the Expectation-Maximization (EM) algorithm is improved and becomes the CM-EM algorithm, which can outperform the EM algorithm when mixture ratios are imbalanced, or local convergence exists. The CM iteration algorithm needs to combine neural networks for MMI classifications on high-dimensional feature spaces. LBI needs further studies for the unification of statistics and logic.