In today's world of fast-paced advancements in artificial intelligence, understanding and improving the effectiveness of models is incredibly important. Our research introduces a new way of combining models based on fuzzy rules with a technique called gradient boosting, aiming to balance the clarity of the model with its performance. This balance is particularly crucial in fields such as healthcare, finance, and policy-making, where making accurate and understandable decisions is essential. Our approach includes a dynamic control factor, which not only prevents any single model from becoming too dominant but also encourages diversity, serving as a sort of adjustment knob. Moreover, our model can adjust itself dynamically based on feedback from a set of validation data, a feature not typically found in traditional systems. Experimental results show that our method is effective at reducing overfitting and complexity, two common challenges in AI models.

The integration of different learning paradigms has long been a focus of machine learning research, aimed at overcoming the inherent limitations of individual methods. Fuzzy rule-based models excel in interpretability and have seen widespread application across diverse fields. However, they face challenges such as complex design specifications and scalability issues with large datasets. The fusion of different techniques and strategies, particularly gradient boosting, with fuzzy rule-based models offers a robust solution to these challenges. This article proposes an integrated fusion framework that merges the strengths of both paradigms to enhance model performance and interpretability. At each iteration, a fuzzy rule-based model is constructed and controlled by a dynamic factor to optimize its contribution to the overall ensemble. This control factor serves multiple purposes: it prevents model dominance, encourages diversity, acts as a regularization parameter, and provides a mechanis...